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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2012 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* Benjamin Gregoire, Laurent Thery, INRIA, 2007 *)
(************************************************************************)
(** * NMake *)
(** From a cyclic Z/nZ representation to arbitrary precision natural numbers.*)
(** NB: This file contain the part which is independent from the underlying
representation. The representation-dependent (and macro-generated) part
is now in [NMake_gen]. *)
Require Import Bool BigNumPrelude ZArith Nnat Ndigits CyclicAxioms DoubleType
Nbasic Wf_nat StreamMemo NSig NMake_gen.
Module Make (W0:CyclicType) <: NType.
(** Let's include the macro-generated part. Even if we can't functorize
things (due to Eval red_t below), the rest of the module only uses
elements mentionned in interface [NAbstract]. *)
Include NMake_gen.Make W0.
Open Scope Z_scope.
Local Notation "[ x ]" := (to_Z x).
Definition eq (x y : t) := [x] = [y].
Declare Reduction red_t :=
lazy beta iota delta
[iter_t reduce same_level mk_t mk_t_S succ_t dom_t dom_op].
Ltac red_t :=
match goal with |- ?u => let v := (eval red_t in u) in change v end.
(** * Generic results *)
Tactic Notation "destr_t" constr(x) "as" simple_intropattern(pat) :=
destruct (destr_t x) as pat; cbv zeta;
rewrite ?iter_mk_t, ?spec_mk_t, ?spec_reduce.
Lemma spec_same_level : forall A (P:Z->Z->A->Prop)
(f : forall n, dom_t n -> dom_t n -> A),
(forall n x y, P (ZnZ.to_Z x) (ZnZ.to_Z y) (f n x y)) ->
forall x y, P [x] [y] (same_level f x y).
Proof.
intros. apply spec_same_level_dep with (P:=fun _ => P); auto.
Qed.
Theorem spec_pos: forall x, 0 <= [x].
Proof.
intros x. destr_t x as (n,x). now case (ZnZ.spec_to_Z x).
Qed.
Lemma digits_dom_op_incr : forall n m, (n<=m)%nat ->
(ZnZ.digits (dom_op n) <= ZnZ.digits (dom_op m))%positive.
Proof.
intros.
change (Zpos (ZnZ.digits (dom_op n)) <= Zpos (ZnZ.digits (dom_op m))).
rewrite !digits_dom_op, !Pshiftl_nat_Zpower.
apply Z.mul_le_mono_nonneg_l; auto with zarith.
apply Z.pow_le_mono_r; auto with zarith.
Qed.
Definition to_N (x : t) := Z.to_N (to_Z x).
(** * Zero, One *)
Definition zero := mk_t O ZnZ.zero.
Definition one := mk_t O ZnZ.one.
Theorem spec_0: [zero] = 0.
Proof.
unfold zero. rewrite spec_mk_t. exact ZnZ.spec_0.
Qed.
Theorem spec_1: [one] = 1.
Proof.
unfold one. rewrite spec_mk_t. exact ZnZ.spec_1.
Qed.
(** * Successor *)
(** NB: it is crucial here and for the rest of this file to preserve
the let-in's. They allow to pre-compute once and for all the
field access to Z/nZ initial structures (when n=0..6). *)
Local Notation succn := (fun n =>
let op := dom_op n in
let succ_c := ZnZ.succ_c in
let one := ZnZ.one in
fun x => match succ_c x with
| C0 r => mk_t n r
| C1 r => mk_t_S n (WW one r)
end).
Definition succ : t -> t := Eval red_t in iter_t succn.
Lemma succ_fold : succ = iter_t succn.
Proof. red_t; reflexivity. Qed.
Theorem spec_succ: forall n, [succ n] = [n] + 1.
Proof.
intros x. rewrite succ_fold. destr_t x as (n,x).
generalize (ZnZ.spec_succ_c x); case ZnZ.succ_c.
intros. rewrite spec_mk_t. assumption.
intros. unfold interp_carry in *.
rewrite spec_mk_t_S. simpl. rewrite ZnZ.spec_1. assumption.
Qed.
(** Two *)
(** Not really pretty, but since W0 might be Z/2Z, we're not sure
there's a proper 2 there. *)
Definition two := succ one.
Lemma spec_2 : [two] = 2.
Proof.
unfold two. now rewrite spec_succ, spec_1.
Qed.
(** * Addition *)
Local Notation addn := (fun n =>
let op := dom_op n in
let add_c := ZnZ.add_c in
let one := ZnZ.one in
fun x y =>match add_c x y with
| C0 r => mk_t n r
| C1 r => mk_t_S n (WW one r)
end).
Definition add : t -> t -> t := Eval red_t in same_level addn.
Lemma add_fold : add = same_level addn.
Proof. red_t; reflexivity. Qed.
Theorem spec_add: forall x y, [add x y] = [x] + [y].
Proof.
intros x y. rewrite add_fold. apply spec_same_level; clear x y.
intros n x y. simpl.
generalize (ZnZ.spec_add_c x y); case ZnZ.add_c; intros z H.
rewrite spec_mk_t. assumption.
rewrite spec_mk_t_S. unfold interp_carry in H.
simpl. rewrite ZnZ.spec_1. assumption.
Qed.
(** * Predecessor *)
Local Notation predn := (fun n =>
let pred_c := ZnZ.pred_c in
fun x => match pred_c x with
| C0 r => reduce n r
| C1 _ => zero
end).
Definition pred : t -> t := Eval red_t in iter_t predn.
Lemma pred_fold : pred = iter_t predn.
Proof. red_t; reflexivity. Qed.
Theorem spec_pred_pos : forall x, 0 < [x] -> [pred x] = [x] - 1.
Proof.
intros x. rewrite pred_fold. destr_t x as (n,x). intros H.
generalize (ZnZ.spec_pred_c x); case ZnZ.pred_c; intros y H'.
rewrite spec_reduce. assumption.
exfalso. unfold interp_carry in *.
generalize (ZnZ.spec_to_Z x) (ZnZ.spec_to_Z y); auto with zarith.
Qed.
Theorem spec_pred0 : forall x, [x] = 0 -> [pred x] = 0.
Proof.
intros x. rewrite pred_fold. destr_t x as (n,x). intros H.
generalize (ZnZ.spec_pred_c x); case ZnZ.pred_c; intros y H'.
rewrite spec_reduce.
unfold interp_carry in H'.
generalize (ZnZ.spec_to_Z y); auto with zarith.
exact spec_0.
Qed.
Lemma spec_pred x : [pred x] = Z.max 0 ([x]-1).
Proof.
rewrite Z.max_comm.
destruct (Z.max_spec ([x]-1) 0) as [(H,->)|(H,->)].
- apply spec_pred0; generalize (spec_pos x); auto with zarith.
- apply spec_pred_pos; auto with zarith.
Qed.
(** * Subtraction *)
Local Notation subn := (fun n =>
let sub_c := ZnZ.sub_c in
fun x y => match sub_c x y with
| C0 r => reduce n r
| C1 r => zero
end).
Definition sub : t -> t -> t := Eval red_t in same_level subn.
Lemma sub_fold : sub = same_level subn.
Proof. red_t; reflexivity. Qed.
Theorem spec_sub_pos : forall x y, [y] <= [x] -> [sub x y] = [x] - [y].
Proof.
intros x y. rewrite sub_fold. apply spec_same_level. clear x y.
intros n x y. simpl.
generalize (ZnZ.spec_sub_c x y); case ZnZ.sub_c; intros z H LE.
rewrite spec_reduce. assumption.
unfold interp_carry in H.
exfalso.
generalize (ZnZ.spec_to_Z z); auto with zarith.
Qed.
Theorem spec_sub0 : forall x y, [x] < [y] -> [sub x y] = 0.
Proof.
intros x y. rewrite sub_fold. apply spec_same_level. clear x y.
intros n x y. simpl.
generalize (ZnZ.spec_sub_c x y); case ZnZ.sub_c; intros z H LE.
rewrite spec_reduce.
unfold interp_carry in H.
generalize (ZnZ.spec_to_Z z); auto with zarith.
exact spec_0.
Qed.
Lemma spec_sub : forall x y, [sub x y] = Z.max 0 ([x]-[y]).
Proof.
intros. destruct (Z.le_gt_cases [y] [x]).
rewrite Z.max_r; auto with zarith. apply spec_sub_pos; auto.
rewrite Z.max_l; auto with zarith. apply spec_sub0; auto.
Qed.
(** * Comparison *)
Definition comparen_m n :
forall m, word (dom_t n) (S m) -> dom_t n -> comparison :=
let op := dom_op n in
let zero := @ZnZ.zero _ op in
let compare := @ZnZ.compare _ op in
let compare0 := compare zero in
fun m => compare_mn_1 (dom_t n) (dom_t n) zero compare compare0 compare (S m).
Let spec_comparen_m:
forall n m (x : word (dom_t n) (S m)) (y : dom_t n),
comparen_m n m x y = Z.compare (eval n (S m) x) (ZnZ.to_Z y).
Proof.
intros n m x y.
unfold comparen_m, eval.
rewrite nmake_double.
apply spec_compare_mn_1.
exact ZnZ.spec_0.
intros. apply ZnZ.spec_compare.
exact ZnZ.spec_to_Z.
exact ZnZ.spec_compare.
exact ZnZ.spec_compare.
exact ZnZ.spec_to_Z.
Qed.
Definition comparenm n m wx wy :=
let mn := Max.max n m in
let d := diff n m in
let op := make_op mn in
ZnZ.compare
(castm (diff_r n m) (extend_tr wx (snd d)))
(castm (diff_l n m) (extend_tr wy (fst d))).
Local Notation compare_folded :=
(iter_sym _
(fun n => @ZnZ.compare _ (dom_op n))
comparen_m
comparenm
CompOpp).
Definition compare : t -> t -> comparison :=
Eval lazy beta iota delta [iter_sym dom_op dom_t comparen_m] in
compare_folded.
Lemma compare_fold : compare = compare_folded.
Proof.
lazy beta iota delta [iter_sym dom_op dom_t comparen_m]. reflexivity.
Qed.
Theorem spec_compare : forall x y,
compare x y = Z.compare [x] [y].
Proof.
intros x y. rewrite compare_fold. apply spec_iter_sym; clear x y.
intros. apply ZnZ.spec_compare.
intros. cbv beta zeta. apply spec_comparen_m.
intros n m x y; unfold comparenm.
rewrite (spec_cast_l n m x), (spec_cast_r n m y).
unfold to_Z; apply ZnZ.spec_compare.
intros. subst. now rewrite <- Z.compare_antisym.
Qed.
Definition eqb (x y : t) : bool :=
match compare x y with
| Eq => true
| _ => false
end.
Theorem spec_eqb x y : eqb x y = Z.eqb [x] [y].
Proof.
apply eq_iff_eq_true.
unfold eqb. rewrite Z.eqb_eq, <- Z.compare_eq_iff, spec_compare.
split; [now destruct Z.compare | now intros ->].
Qed.
Definition lt (n m : t) := [n] < [m].
Definition le (n m : t) := [n] <= [m].
Definition ltb (x y : t) : bool :=
match compare x y with
| Lt => true
| _ => false
end.
Theorem spec_ltb x y : ltb x y = Z.ltb [x] [y].
Proof.
apply eq_iff_eq_true.
rewrite Z.ltb_lt. unfold Z.lt, ltb. rewrite spec_compare.
split; [now destruct Z.compare | now intros ->].
Qed.
Definition leb (x y : t) : bool :=
match compare x y with
| Gt => false
| _ => true
end.
Theorem spec_leb x y : leb x y = Z.leb [x] [y].
Proof.
apply eq_iff_eq_true.
rewrite Z.leb_le. unfold Z.le, leb. rewrite spec_compare.
destruct Z.compare; split; try easy. now destruct 1.
Qed.
Definition min (n m : t) : t := match compare n m with Gt => m | _ => n end.
Definition max (n m : t) : t := match compare n m with Lt => m | _ => n end.
Theorem spec_max : forall n m, [max n m] = Z.max [n] [m].
Proof.
intros. unfold max, Z.max. rewrite spec_compare; destruct Z.compare; reflexivity.
Qed.
Theorem spec_min : forall n m, [min n m] = Z.min [n] [m].
Proof.
intros. unfold min, Z.min. rewrite spec_compare; destruct Z.compare; reflexivity.
Qed.
(** * Multiplication *)
Definition wn_mul n : forall m, word (dom_t n) (S m) -> dom_t n -> t :=
let op := dom_op n in
let zero := @ZnZ.zero _ op in
let succ := @ZnZ.succ _ op in
let add_c := @ZnZ.add_c _ op in
let mul_c := @ZnZ.mul_c _ op in
let ww := @ZnZ.WW _ op in
let ow := @ZnZ.OW _ op in
let eq0 := @ZnZ.eq0 _ op in
let mul_add := @DoubleMul.w_mul_add _ zero succ add_c mul_c in
let mul_add_n1 := @DoubleMul.double_mul_add_n1 _ zero ww ow mul_add in
fun m x y =>
let (w,r) := mul_add_n1 (S m) x y zero in
if eq0 w then mk_t_w' n m r
else mk_t_w' n (S m) (WW (extend n m w) r).
Definition mulnm n m x y :=
let mn := Max.max n m in
let d := diff n m in
let op := make_op mn in
reduce_n (S mn) (ZnZ.mul_c
(castm (diff_r n m) (extend_tr x (snd d)))
(castm (diff_l n m) (extend_tr y (fst d)))).
Local Notation mul_folded :=
(iter_sym _
(fun n => let mul_c := ZnZ.mul_c in
fun x y => reduce (S n) (succ_t _ (mul_c x y)))
wn_mul
mulnm
(fun x => x)).
Definition mul : t -> t -> t :=
Eval lazy beta iota delta
[iter_sym dom_op dom_t reduce succ_t extend zeron
wn_mul DoubleMul.w_mul_add mk_t_w'] in
mul_folded.
Lemma mul_fold : mul = mul_folded.
Proof.
lazy beta iota delta
[iter_sym dom_op dom_t reduce succ_t extend zeron
wn_mul DoubleMul.w_mul_add mk_t_w']. reflexivity.
Qed.
Lemma spec_muln:
forall n (x: word _ (S n)) y,
[Nn (S n) (ZnZ.mul_c (Ops:=make_op n) x y)] = [Nn n x] * [Nn n y].
Proof.
intros n x y; unfold to_Z.
rewrite <- ZnZ.spec_mul_c.
rewrite make_op_S.
case ZnZ.mul_c; auto.
Qed.
Lemma spec_mul_add_n1: forall n m x y z,
let (q,r) := DoubleMul.double_mul_add_n1 ZnZ.zero ZnZ.WW ZnZ.OW
(DoubleMul.w_mul_add ZnZ.zero ZnZ.succ ZnZ.add_c ZnZ.mul_c)
(S m) x y z in
ZnZ.to_Z q * (base (ZnZ.digits (nmake_op _ (dom_op n) (S m))))
+ eval n (S m) r =
eval n (S m) x * ZnZ.to_Z y + ZnZ.to_Z z.
Proof.
intros n m x y z.
rewrite digits_nmake.
unfold eval. rewrite nmake_double.
apply DoubleMul.spec_double_mul_add_n1.
apply ZnZ.spec_0.
exact ZnZ.spec_WW.
exact ZnZ.spec_OW.
apply DoubleCyclic.spec_mul_add.
Qed.
Lemma spec_wn_mul : forall n m x y,
[wn_mul n m x y] = (eval n (S m) x) * ZnZ.to_Z y.
Proof.
intros; unfold wn_mul.
generalize (spec_mul_add_n1 n m x y ZnZ.zero).
case DoubleMul.double_mul_add_n1; intros q r Hqr.
rewrite ZnZ.spec_0, Z.add_0_r in Hqr. rewrite <- Hqr.
generalize (ZnZ.spec_eq0 q); case ZnZ.eq0; intros HH.
rewrite HH; auto. simpl. apply spec_mk_t_w'.
clear.
rewrite spec_mk_t_w'.
set (m' := S m) in *.
unfold eval.
rewrite nmake_WW. f_equal. f_equal.
rewrite <- spec_mk_t.
symmetry. apply spec_extend.
Qed.
Theorem spec_mul : forall x y, [mul x y] = [x] * [y].
Proof.
intros x y. rewrite mul_fold. apply spec_iter_sym; clear x y.
intros n x y. cbv zeta beta.
rewrite spec_reduce, spec_succ_t, <- ZnZ.spec_mul_c; auto.
apply spec_wn_mul.
intros n m x y; unfold mulnm. rewrite spec_reduce_n.
rewrite (spec_cast_l n m x), (spec_cast_r n m y).
apply spec_muln.
intros. rewrite Z.mul_comm; auto.
Qed.
(** * Division by a smaller number *)
Definition wn_divn1 n :=
let op := dom_op n in
let zd := ZnZ.zdigits op in
let zero := @ZnZ.zero _ op in
let ww := @ZnZ.WW _ op in
let head0 := @ZnZ.head0 _ op in
let add_mul_div := @ZnZ.add_mul_div _ op in
let div21 := @ZnZ.div21 _ op in
let compare := @ZnZ.compare _ op in
let sub := @ZnZ.sub _ op in
let ddivn1 :=
DoubleDivn1.double_divn1 zd zero ww head0 add_mul_div div21 compare sub in
fun m x y => let (u,v) := ddivn1 (S m) x y in (mk_t_w' n m u, mk_t n v).
Let div_gtnm n m wx wy :=
let mn := Max.max n m in
let d := diff n m in
let op := make_op mn in
let (q, r):= ZnZ.div_gt
(castm (diff_r n m) (extend_tr wx (snd d)))
(castm (diff_l n m) (extend_tr wy (fst d))) in
(reduce_n mn q, reduce_n mn r).
Local Notation div_gt_folded :=
(iter _
(fun n => let div_gt := ZnZ.div_gt in
fun x y => let (u,v) := div_gt x y in (reduce n u, reduce n v))
(fun n =>
let div_gt := ZnZ.div_gt in
fun m x y =>
let y' := DoubleBase.get_low (zeron n) (S m) y in
let (u,v) := div_gt x y' in (reduce n u, reduce n v))
wn_divn1
div_gtnm).
Definition div_gt :=
Eval lazy beta iota delta
[iter dom_op dom_t reduce zeron wn_divn1 mk_t_w' mk_t] in
div_gt_folded.
Lemma div_gt_fold : div_gt = div_gt_folded.
Proof.
lazy beta iota delta [iter dom_op dom_t reduce zeron wn_divn1 mk_t_w' mk_t].
reflexivity.
Qed.
Lemma spec_get_endn: forall n m x y,
eval n m x <= [mk_t n y] ->
[mk_t n (DoubleBase.get_low (zeron n) m x)] = eval n m x.
Proof.
intros n m x y H.
unfold eval. rewrite nmake_double.
rewrite spec_mk_t in *.
apply DoubleBase.spec_get_low.
apply spec_zeron.
exact ZnZ.spec_to_Z.
apply Z.le_lt_trans with (ZnZ.to_Z y); auto.
rewrite <- nmake_double; auto.
case (ZnZ.spec_to_Z y); auto.
Qed.
Let spec_divn1 n :=
DoubleDivn1.spec_double_divn1
(ZnZ.zdigits (dom_op n)) (ZnZ.zero:dom_t n)
ZnZ.WW ZnZ.head0
ZnZ.add_mul_div ZnZ.div21
ZnZ.compare ZnZ.sub ZnZ.to_Z
ZnZ.spec_to_Z
ZnZ.spec_zdigits
ZnZ.spec_0 ZnZ.spec_WW ZnZ.spec_head0
ZnZ.spec_add_mul_div ZnZ.spec_div21
ZnZ.spec_compare ZnZ.spec_sub.
Lemma spec_div_gt_aux : forall x y, [x] > [y] -> 0 < [y] ->
let (q,r) := div_gt x y in
[x] = [q] * [y] + [r] /\ 0 <= [r] < [y].
Proof.
intros x y. rewrite div_gt_fold. apply spec_iter; clear x y.
intros n x y H1 H2. simpl.
generalize (ZnZ.spec_div_gt x y H1 H2); case ZnZ.div_gt.
intros u v. rewrite 2 spec_reduce. auto.
intros n m x y H1 H2. cbv zeta beta.
generalize (ZnZ.spec_div_gt x
(DoubleBase.get_low (zeron n) (S m) y)).
case ZnZ.div_gt.
intros u v H3; repeat rewrite spec_reduce.
generalize (spec_get_endn n (S m) y x). rewrite !spec_mk_t. intros H4.
rewrite H4 in H3; auto with zarith.
intros n m x y H1 H2.
generalize (spec_divn1 n (S m) x y H2).
unfold wn_divn1; case DoubleDivn1.double_divn1.
intros u v H3.
rewrite spec_mk_t_w', spec_mk_t.
rewrite <- !nmake_double in H3; auto.
intros n m x y H1 H2; unfold div_gtnm.
generalize (ZnZ.spec_div_gt
(castm (diff_r n m)
(extend_tr x (snd (diff n m))))
(castm (diff_l n m)
(extend_tr y (fst (diff n m))))).
case ZnZ.div_gt.
intros xx yy HH.
repeat rewrite spec_reduce_n.
rewrite (spec_cast_l n m x), (spec_cast_r n m y).
unfold to_Z; apply HH.
rewrite (spec_cast_l n m x) in H1; auto.
rewrite (spec_cast_r n m y) in H1; auto.
rewrite (spec_cast_r n m y) in H2; auto.
Qed.
Theorem spec_div_gt: forall x y, [x] > [y] -> 0 < [y] ->
let (q,r) := div_gt x y in
[q] = [x] / [y] /\ [r] = [x] mod [y].
Proof.
intros x y H1 H2; generalize (spec_div_gt_aux x y H1 H2); case div_gt.
intros q r (H3, H4); split.
apply (Zdiv_unique [x] [y] [q] [r]); auto.
rewrite Z.mul_comm; auto.
apply (Zmod_unique [x] [y] [q] [r]); auto.
rewrite Z.mul_comm; auto.
Qed.
(** * General Division *)
Definition div_eucl (x y : t) : t * t :=
if eqb y zero then (zero,zero) else
match compare x y with
| Eq => (one, zero)
| Lt => (zero, x)
| Gt => div_gt x y
end.
Theorem spec_div_eucl: forall x y,
let (q,r) := div_eucl x y in
([q], [r]) = Z.div_eucl [x] [y].
Proof.
intros x y. unfold div_eucl.
rewrite spec_eqb, spec_compare, spec_0.
case Z.eqb_spec.
intros ->. rewrite spec_0. destruct [x]; auto.
intros H'.
assert (H : 0 < [y]) by (generalize (spec_pos y); auto with zarith).
clear H'.
case Z.compare_spec; intros Cmp;
rewrite ?spec_0, ?spec_1; intros; auto with zarith.
rewrite Cmp; generalize (Z_div_same [y] (Z.lt_gt _ _ H))
(Z_mod_same [y] (Z.lt_gt _ _ H));
unfold Z.div, Z.modulo; case Z.div_eucl; intros; subst; auto.
assert (LeLt: 0 <= [x] < [y]) by (generalize (spec_pos x); auto).
generalize (Zdiv_small _ _ LeLt) (Zmod_small _ _ LeLt);
unfold Z.div, Z.modulo; case Z.div_eucl; intros; subst; auto.
generalize (spec_div_gt _ _ (Z.lt_gt _ _ Cmp) H); auto.
unfold Z.div, Z.modulo; case Z.div_eucl; case div_gt.
intros a b c d (H1, H2); subst; auto.
Qed.
Definition div (x y : t) : t := fst (div_eucl x y).
Theorem spec_div:
forall x y, [div x y] = [x] / [y].
Proof.
intros x y; unfold div; generalize (spec_div_eucl x y);
case div_eucl; simpl fst.
intros xx yy; unfold Z.div; case Z.div_eucl; intros qq rr H;
injection H; auto.
Qed.
(** * Modulo by a smaller number *)
Definition wn_modn1 n :=
let op := dom_op n in
let zd := ZnZ.zdigits op in
let zero := @ZnZ.zero _ op in
let head0 := @ZnZ.head0 _ op in
let add_mul_div := @ZnZ.add_mul_div _ op in
let div21 := @ZnZ.div21 _ op in
let compare := @ZnZ.compare _ op in
let sub := @ZnZ.sub _ op in
let dmodn1 :=
DoubleDivn1.double_modn1 zd zero head0 add_mul_div div21 compare sub in
fun m x y => reduce n (dmodn1 (S m) x y).
Let mod_gtnm n m wx wy :=
let mn := Max.max n m in
let d := diff n m in
let op := make_op mn in
reduce_n mn (ZnZ.modulo_gt
(castm (diff_r n m) (extend_tr wx (snd d)))
(castm (diff_l n m) (extend_tr wy (fst d)))).
Local Notation mod_gt_folded :=
(iter _
(fun n => let modulo_gt := ZnZ.modulo_gt in
fun x y => reduce n (modulo_gt x y))
(fun n => let modulo_gt := ZnZ.modulo_gt in
fun m x y =>
reduce n (modulo_gt x (DoubleBase.get_low (zeron n) (S m) y)))
wn_modn1
mod_gtnm).
Definition mod_gt :=
Eval lazy beta iota delta [iter dom_op dom_t reduce wn_modn1 zeron] in
mod_gt_folded.
Lemma mod_gt_fold : mod_gt = mod_gt_folded.
Proof.
lazy beta iota delta [iter dom_op dom_t reduce wn_modn1 zeron].
reflexivity.
Qed.
Let spec_modn1 n :=
DoubleDivn1.spec_double_modn1
(ZnZ.zdigits (dom_op n)) (ZnZ.zero:dom_t n)
ZnZ.WW ZnZ.head0
ZnZ.add_mul_div ZnZ.div21
ZnZ.compare ZnZ.sub ZnZ.to_Z
ZnZ.spec_to_Z
ZnZ.spec_zdigits
ZnZ.spec_0 ZnZ.spec_WW ZnZ.spec_head0
ZnZ.spec_add_mul_div ZnZ.spec_div21
ZnZ.spec_compare ZnZ.spec_sub.
Theorem spec_mod_gt:
forall x y, [x] > [y] -> 0 < [y] -> [mod_gt x y] = [x] mod [y].
Proof.
intros x y. rewrite mod_gt_fold. apply spec_iter; clear x y.
intros n x y H1 H2. simpl. rewrite spec_reduce.
exact (ZnZ.spec_modulo_gt x y H1 H2).
intros n m x y H1 H2. cbv zeta beta. rewrite spec_reduce.
rewrite <- spec_mk_t in H1.
rewrite <- (spec_get_endn n (S m) y x); auto with zarith.
rewrite spec_mk_t.
apply ZnZ.spec_modulo_gt; auto.
rewrite <- (spec_get_endn n (S m) y x), !spec_mk_t in H1; auto with zarith.
rewrite <- (spec_get_endn n (S m) y x), !spec_mk_t in H2; auto with zarith.
intros n m x y H1 H2. unfold wn_modn1. rewrite spec_reduce.
unfold eval; rewrite nmake_double.
apply (spec_modn1 n); auto.
intros n m x y H1 H2; unfold mod_gtnm.
repeat rewrite spec_reduce_n.
rewrite (spec_cast_l n m x), (spec_cast_r n m y).
unfold to_Z; apply ZnZ.spec_modulo_gt.
rewrite (spec_cast_l n m x) in H1; auto.
rewrite (spec_cast_r n m y) in H1; auto.
rewrite (spec_cast_r n m y) in H2; auto.
Qed.
(** * General Modulo *)
Definition modulo (x y : t) : t :=
if eqb y zero then zero else
match compare x y with
| Eq => zero
| Lt => x
| Gt => mod_gt x y
end.
Theorem spec_modulo:
forall x y, [modulo x y] = [x] mod [y].
Proof.
intros x y. unfold modulo.
rewrite spec_eqb, spec_compare, spec_0.
case Z.eqb_spec.
intros ->; rewrite spec_0. destruct [x]; auto.
intro H'.
assert (H : 0 < [y]) by (generalize (spec_pos y); auto with zarith).
clear H'.
case Z.compare_spec;
rewrite ?spec_0, ?spec_1; intros; try split; auto with zarith.
rewrite H0; symmetry; apply Z_mod_same; auto with zarith.
symmetry; apply Zmod_small; auto with zarith.
generalize (spec_pos x); auto with zarith.
apply spec_mod_gt; auto with zarith.
Qed.
(** * Square *)
Local Notation squaren := (fun n =>
let square_c := ZnZ.square_c in
fun x => reduce (S n) (succ_t _ (square_c x))).
Definition square : t -> t := Eval red_t in iter_t squaren.
Lemma square_fold : square = iter_t squaren.
Proof. red_t; reflexivity. Qed.
Theorem spec_square: forall x, [square x] = [x] * [x].
Proof.
intros x. rewrite square_fold. destr_t x as (n,x).
rewrite spec_succ_t. exact (ZnZ.spec_square_c x).
Qed.
(** * Square Root *)
Local Notation sqrtn := (fun n =>
let sqrt := ZnZ.sqrt in
fun x => reduce n (sqrt x)).
Definition sqrt : t -> t := Eval red_t in iter_t sqrtn.
Lemma sqrt_fold : sqrt = iter_t sqrtn.
Proof. red_t; reflexivity. Qed.
Theorem spec_sqrt_aux: forall x, [sqrt x] ^ 2 <= [x] < ([sqrt x] + 1) ^ 2.
Proof.
intros x. rewrite sqrt_fold. destr_t x as (n,x). exact (ZnZ.spec_sqrt x).
Qed.
Theorem spec_sqrt: forall x, [sqrt x] = Z.sqrt [x].
Proof.
intros x.
symmetry. apply Z.sqrt_unique.
rewrite <- ! Z.pow_2_r. apply spec_sqrt_aux.
Qed.
(** * Power *)
Fixpoint pow_pos (x:t)(p:positive) : t :=
match p with
| xH => x
| xO p => square (pow_pos x p)
| xI p => mul (square (pow_pos x p)) x
end.
Theorem spec_pow_pos: forall x n, [pow_pos x n] = [x] ^ Zpos n.
Proof.
intros x n; generalize x; elim n; clear n x; simpl pow_pos.
intros; rewrite spec_mul; rewrite spec_square; rewrite H.
rewrite Pos2Z.inj_xI; rewrite Zpower_exp; auto with zarith.
rewrite (Z.mul_comm 2); rewrite Z.pow_mul_r; auto with zarith.
rewrite Z.pow_2_r; rewrite Z.pow_1_r; auto.
intros; rewrite spec_square; rewrite H.
rewrite Pos2Z.inj_xO; auto with zarith.
rewrite (Z.mul_comm 2); rewrite Z.pow_mul_r; auto with zarith.
rewrite Z.pow_2_r; auto.
intros; rewrite Z.pow_1_r; auto.
Qed.
Definition pow_N (x:t)(n:N) : t := match n with
| BinNat.N0 => one
| BinNat.Npos p => pow_pos x p
end.
Theorem spec_pow_N: forall x n, [pow_N x n] = [x] ^ Z.of_N n.
Proof.
destruct n; simpl. apply spec_1.
apply spec_pow_pos.
Qed.
Definition pow (x y:t) : t := pow_N x (to_N y).
Theorem spec_pow : forall x y, [pow x y] = [x] ^ [y].
Proof.
intros. unfold pow, to_N.
now rewrite spec_pow_N, Z2N.id by apply spec_pos.
Qed.
(** * digits
Number of digits in the representation of a numbers
(including head zero's).
NB: This function isn't a morphism for setoid [eq].
*)
Local Notation digitsn := (fun n =>
let digits := ZnZ.digits (dom_op n) in
fun _ => digits).
Definition digits : t -> positive := Eval red_t in iter_t digitsn.
Lemma digits_fold : digits = iter_t digitsn.
Proof. red_t; reflexivity. Qed.
Theorem spec_digits: forall x, 0 <= [x] < 2 ^ Zpos (digits x).
Proof.
intros x. rewrite digits_fold. destr_t x as (n,x). exact (ZnZ.spec_to_Z x).
Qed.
Lemma digits_level : forall x, digits x = ZnZ.digits (dom_op (level x)).
Proof.
intros x. rewrite digits_fold. unfold level. destr_t x as (n,x). reflexivity.
Qed.
(** * Gcd *)
Definition gcd_gt_body a b cont :=
match compare b zero with
| Gt =>
let r := mod_gt a b in
match compare r zero with
| Gt => cont r (mod_gt b r)
| _ => b
end
| _ => a
end.
Theorem Zspec_gcd_gt_body: forall a b cont p,
[a] > [b] -> [a] < 2 ^ p ->
(forall a1 b1, [a1] < 2 ^ (p - 1) -> [a1] > [b1] ->
Zis_gcd [a1] [b1] [cont a1 b1]) ->
Zis_gcd [a] [b] [gcd_gt_body a b cont].
Proof.
intros a b cont p H2 H3 H4; unfold gcd_gt_body.
rewrite ! spec_compare, spec_0. case Z.compare_spec.
intros ->; apply Zis_gcd_0.
intros HH; absurd (0 <= [b]); auto with zarith.
case (spec_digits b); auto with zarith.
intros H5; case Z.compare_spec.
intros H6; rewrite <- (Z.mul_1_r [b]).
rewrite (Z_div_mod_eq [a] [b]); auto with zarith.
rewrite <- spec_mod_gt; auto with zarith.
rewrite H6; rewrite Z.add_0_r.
apply Zis_gcd_mult; apply Zis_gcd_1.
intros; apply False_ind.
case (spec_digits (mod_gt a b)); auto with zarith.
intros H6; apply DoubleDiv.Zis_gcd_mod; auto with zarith.
apply DoubleDiv.Zis_gcd_mod; auto with zarith.
rewrite <- spec_mod_gt; auto with zarith.
assert (F2: [b] > [mod_gt a b]).
case (Z_mod_lt [a] [b]); auto with zarith.
repeat rewrite <- spec_mod_gt; auto with zarith.
assert (F3: [mod_gt a b] > [mod_gt b (mod_gt a b)]).
case (Z_mod_lt [b] [mod_gt a b]); auto with zarith.
rewrite <- spec_mod_gt; auto with zarith.
repeat rewrite <- spec_mod_gt; auto with zarith.
apply H4; auto with zarith.
apply Z.mul_lt_mono_pos_r with 2; auto with zarith.
apply Z.le_lt_trans with ([b] + [mod_gt a b]); auto with zarith.
apply Z.le_lt_trans with (([a]/[b]) * [b] + [mod_gt a b]); auto with zarith.
- apply Z.add_le_mono_r.
rewrite <- (Z.mul_1_l [b]) at 1.
apply Z.mul_le_mono_nonneg_r; auto with zarith.
change 1 with (Z.succ 0). apply Z.le_succ_l.
apply Z.div_str_pos; auto with zarith.
- rewrite Z.mul_comm; rewrite spec_mod_gt; auto with zarith.
rewrite <- Z_div_mod_eq; auto with zarith.
rewrite Z.mul_comm, <- Z.pow_succ_r, Z.sub_1_r, Z.succ_pred; auto.
apply Z.le_0_sub. change 1 with (Z.succ 0). apply Z.le_succ_l.
destruct p; simpl in H3; auto with zarith.
Qed.
Fixpoint gcd_gt_aux (p:positive) (cont:t->t->t) (a b:t) : t :=
gcd_gt_body a b
(fun a b =>
match p with
| xH => cont a b
| xO p => gcd_gt_aux p (gcd_gt_aux p cont) a b
| xI p => gcd_gt_aux p (gcd_gt_aux p cont) a b
end).
Theorem Zspec_gcd_gt_aux: forall p n a b cont,
[a] > [b] -> [a] < 2 ^ (Zpos p + n) ->
(forall a1 b1, [a1] < 2 ^ n -> [a1] > [b1] ->
Zis_gcd [a1] [b1] [cont a1 b1]) ->
Zis_gcd [a] [b] [gcd_gt_aux p cont a b].
intros p; elim p; clear p.
intros p Hrec n a b cont H2 H3 H4.
unfold gcd_gt_aux; apply Zspec_gcd_gt_body with (Zpos (xI p) + n); auto.
intros a1 b1 H6 H7.
apply Hrec with (Zpos p + n); auto.
replace (Zpos p + (Zpos p + n)) with
(Zpos (xI p) + n - 1); auto.
rewrite Pos2Z.inj_xI; ring.
intros a2 b2 H9 H10.
apply Hrec with n; auto.
intros p Hrec n a b cont H2 H3 H4.
unfold gcd_gt_aux; apply Zspec_gcd_gt_body with (Zpos (xO p) + n); auto.
intros a1 b1 H6 H7.
apply Hrec with (Zpos p + n - 1); auto.
replace (Zpos p + (Zpos p + n - 1)) with
(Zpos (xO p) + n - 1); auto.
rewrite Pos2Z.inj_xO; ring.
intros a2 b2 H9 H10.
apply Hrec with (n - 1); auto.
replace (Zpos p + (n - 1)) with
(Zpos p + n - 1); auto with zarith.
intros a3 b3 H12 H13; apply H4; auto with zarith.
apply Z.lt_le_trans with (1 := H12).
apply Z.pow_le_mono_r; auto with zarith.
intros n a b cont H H2 H3.
simpl gcd_gt_aux.
apply Zspec_gcd_gt_body with (n + 1); auto with zarith.
rewrite Z.add_comm; auto.
intros a1 b1 H5 H6; apply H3; auto.
replace n with (n + 1 - 1); auto; try ring.
Qed.
Definition gcd_cont a b :=
match compare one b with
| Eq => one
| _ => a
end.
Definition gcd_gt a b := gcd_gt_aux (digits a) gcd_cont a b.
Theorem spec_gcd_gt: forall a b,
[a] > [b] -> [gcd_gt a b] = Z.gcd [a] [b].
Proof.
intros a b H2.
case (spec_digits (gcd_gt a b)); intros H3 H4.
case (spec_digits a); intros H5 H6.
symmetry; apply Zis_gcd_gcd; auto with zarith.
unfold gcd_gt; apply Zspec_gcd_gt_aux with 0; auto with zarith.
intros a1 a2; rewrite Z.pow_0_r.
case (spec_digits a2); intros H7 H8;
intros; apply False_ind; auto with zarith.
Qed.
Definition gcd (a b : t) : t :=
match compare a b with
| Eq => a
| Lt => gcd_gt b a
| Gt => gcd_gt a b
end.
Theorem spec_gcd: forall a b, [gcd a b] = Z.gcd [a] [b].
Proof.
intros a b.
case (spec_digits a); intros H1 H2.
case (spec_digits b); intros H3 H4.
unfold gcd. rewrite spec_compare. case Z.compare_spec.
intros HH; rewrite HH; symmetry; apply Zis_gcd_gcd; auto.
apply Zis_gcd_refl.
intros; transitivity (Z.gcd [b] [a]).
apply spec_gcd_gt; auto with zarith.
apply Zis_gcd_gcd; auto with zarith.
apply Z.gcd_nonneg.
apply Zis_gcd_sym; apply Zgcd_is_gcd.
intros; apply spec_gcd_gt; auto with zarith.
Qed.
(** * Parity test *)
Definition even : t -> bool := Eval red_t in
iter_t (fun n x => ZnZ.is_even x).
Definition odd x := negb (even x).
Lemma even_fold : even = iter_t (fun n x => ZnZ.is_even x).
Proof. red_t; reflexivity. Qed.
Theorem spec_even_aux: forall x,
if even x then [x] mod 2 = 0 else [x] mod 2 = 1.
Proof.
intros x. rewrite even_fold. destr_t x as (n,x).
exact (ZnZ.spec_is_even x).
Qed.
Theorem spec_even: forall x, even x = Z.even [x].
Proof.
intros x. assert (H := spec_even_aux x). symmetry.
rewrite (Z.div_mod [x] 2); auto with zarith.
destruct (even x); rewrite H, ?Z.add_0_r.
rewrite Zeven_bool_iff. apply Zeven_2p.
apply not_true_is_false. rewrite Zeven_bool_iff.
apply Zodd_not_Zeven. apply Zodd_2p_plus_1.
Qed.
Theorem spec_odd: forall x, odd x = Z.odd [x].
Proof.
intros x. unfold odd.
assert (H := spec_even_aux x). symmetry.
rewrite (Z.div_mod [x] 2); auto with zarith.
destruct (even x); rewrite H, ?Z.add_0_r; simpl negb.
apply not_true_is_false. rewrite Zodd_bool_iff.
apply Zeven_not_Zodd. apply Zeven_2p.
apply Zodd_bool_iff. apply Zodd_2p_plus_1.
Qed.
(** * Conversion *)
Definition pheight p :=
Peano.pred (Pos.to_nat (get_height (ZnZ.digits (dom_op 0)) (plength p))).
Theorem pheight_correct: forall p,
Zpos p < 2 ^ (Zpos (ZnZ.digits (dom_op 0)) * 2 ^ (Z.of_nat (pheight p))).
Proof.
intros p; unfold pheight.
rewrite Nat2Z.inj_pred by apply Pos2Nat.is_pos.
rewrite positive_nat_Z.
rewrite <- Z.sub_1_r.
assert (F2:= (get_height_correct (ZnZ.digits (dom_op 0)) (plength p))).
apply Z.lt_le_trans with (Zpos (Pos.succ p)).
rewrite Pos2Z.inj_succ; auto with zarith.
apply Z.le_trans with (1 := plength_pred_correct (Pos.succ p)).
rewrite Pos.pred_succ.
apply Z.pow_le_mono_r; auto with zarith.
Qed.
Definition of_pos (x:positive) : t :=
let n := pheight x in
reduce n (snd (ZnZ.of_pos x)).
Theorem spec_of_pos: forall x,
[of_pos x] = Zpos x.
Proof.
intros x; unfold of_pos.
rewrite spec_reduce.
simpl.
apply ZnZ.of_pos_correct.
unfold base.
apply Z.lt_le_trans with (1 := pheight_correct x).
apply Z.pow_le_mono_r; auto with zarith.
rewrite (digits_dom_op (_ _)), Pshiftl_nat_Zpower. auto with zarith.
Qed.
Definition of_N (x:N) : t :=
match x with
| BinNat.N0 => zero
| Npos p => of_pos p
end.
Theorem spec_of_N: forall x,
[of_N x] = Z.of_N x.
Proof.
intros x; case x.
simpl of_N. exact spec_0.
intros p; exact (spec_of_pos p).
Qed.
(** * [head0] and [tail0]
Number of zero at the beginning and at the end of
the representation of the number.
NB: these functions are not morphism for setoid [eq].
*)
Local Notation head0n := (fun n =>
let head0 := ZnZ.head0 in
fun x => reduce n (head0 x)).
Definition head0 : t -> t := Eval red_t in iter_t head0n.
Lemma head0_fold : head0 = iter_t head0n.
Proof. red_t; reflexivity. Qed.
Theorem spec_head00: forall x, [x] = 0 -> [head0 x] = Zpos (digits x).
Proof.
intros x. rewrite head0_fold, digits_fold. destr_t x as (n,x).
exact (ZnZ.spec_head00 x).
Qed.
Lemma pow2_pos_minus_1 : forall z, 0<z -> 2^(z-1) = 2^z / 2.
Proof.
intros. apply Zdiv_unique with 0; auto with zarith.
change 2 with (2^1) at 2.
rewrite <- Zpower_exp; auto with zarith.
rewrite Z.add_0_r. f_equal. auto with zarith.
Qed.
Theorem spec_head0: forall x, 0 < [x] ->
2 ^ (Zpos (digits x) - 1) <= 2 ^ [head0 x] * [x] < 2 ^ Zpos (digits x).
Proof.
intros x. rewrite pow2_pos_minus_1 by (red; auto).
rewrite head0_fold, digits_fold. destr_t x as (n,x). exact (ZnZ.spec_head0 x).
Qed.
Local Notation tail0n := (fun n =>
let tail0 := ZnZ.tail0 in
fun x => reduce n (tail0 x)).
Definition tail0 : t -> t := Eval red_t in iter_t tail0n.
Lemma tail0_fold : tail0 = iter_t tail0n.
Proof. red_t; reflexivity. Qed.
Theorem spec_tail00: forall x, [x] = 0 -> [tail0 x] = Zpos (digits x).
Proof.
intros x. rewrite tail0_fold, digits_fold. destr_t x as (n,x).
exact (ZnZ.spec_tail00 x).
Qed.
Theorem spec_tail0: forall x,
0 < [x] -> exists y, 0 <= y /\ [x] = (2 * y + 1) * 2 ^ [tail0 x].
Proof.
intros x. rewrite tail0_fold. destr_t x as (n,x). exact (ZnZ.spec_tail0 x).
Qed.
(** * [Ndigits]
Same as [digits] but encoded using large integers
NB: this function is not a morphism for setoid [eq].
*)
Local Notation Ndigitsn := (fun n =>
let d := reduce n (ZnZ.zdigits (dom_op n)) in
fun _ => d).
Definition Ndigits : t -> t := Eval red_t in iter_t Ndigitsn.
Lemma Ndigits_fold : Ndigits = iter_t Ndigitsn.
Proof. red_t; reflexivity. Qed.
Theorem spec_Ndigits: forall x, [Ndigits x] = Zpos (digits x).
Proof.
intros x. rewrite Ndigits_fold, digits_fold. destr_t x as (n,x).
apply ZnZ.spec_zdigits.
Qed.
(** * Binary logarithm *)
Local Notation log2n := (fun n =>
let op := dom_op n in
let zdigits := ZnZ.zdigits op in
let head0 := ZnZ.head0 in
let sub_carry := ZnZ.sub_carry in
fun x => reduce n (sub_carry zdigits (head0 x))).
Definition log2 : t -> t := Eval red_t in
let log2 := iter_t log2n in
fun x => if eqb x zero then zero else log2 x.
Lemma log2_fold :
log2 = fun x => if eqb x zero then zero else iter_t log2n x.
Proof. red_t; reflexivity. Qed.
Lemma spec_log2_0 : forall x, [x] = 0 -> [log2 x] = 0.
Proof.
intros x H. rewrite log2_fold.
rewrite spec_eqb, H. rewrite spec_0. simpl. exact spec_0.
Qed.
Lemma head0_zdigits : forall n (x : dom_t n),
0 < ZnZ.to_Z x ->
ZnZ.to_Z (ZnZ.head0 x) < ZnZ.to_Z (ZnZ.zdigits (dom_op n)).
Proof.
intros n x H.
destruct (ZnZ.spec_head0 x H) as (_,H0).
intros.
assert (H1 := ZnZ.spec_to_Z (ZnZ.head0 x)).
assert (H2 := ZnZ.spec_to_Z (ZnZ.zdigits (dom_op n))).
unfold base in *.
rewrite ZnZ.spec_zdigits in H2 |- *.
set (h := ZnZ.to_Z (ZnZ.head0 x)) in *; clearbody h.
set (d := ZnZ.digits (dom_op n)) in *; clearbody d.
destruct (Z_lt_le_dec h (Zpos d)); auto. exfalso.
assert (1 * 2^Zpos d <= ZnZ.to_Z x * 2^h).
apply Z.mul_le_mono_nonneg; auto with zarith.
apply Z.pow_le_mono_r; auto with zarith.
rewrite Z.mul_comm in H0. auto with zarith.
Qed.
Lemma spec_log2_pos : forall x, [x]<>0 ->
2^[log2 x] <= [x] < 2^([log2 x]+1).
Proof.
intros x H. rewrite log2_fold.
rewrite spec_eqb. rewrite spec_0.
case Z.eqb_spec.
auto with zarith.
clear H.
destr_t x as (n,x). intros H.
rewrite ZnZ.spec_sub_carry.
assert (H0 := ZnZ.spec_to_Z x).
assert (H1 := ZnZ.spec_to_Z (ZnZ.head0 x)).
assert (H2 := ZnZ.spec_to_Z (ZnZ.zdigits (dom_op n))).
assert (H3 := head0_zdigits n x).
rewrite Zmod_small by auto with zarith.
rewrite Z.sub_simpl_r.
rewrite (Z.mul_lt_mono_pos_l (2^(ZnZ.to_Z (ZnZ.head0 x))));
auto with zarith.
rewrite (Z.mul_le_mono_pos_l _ _ (2^(ZnZ.to_Z (ZnZ.head0 x))));
auto with zarith.
rewrite <- 2 Zpower_exp; auto with zarith.
rewrite !Z.add_sub_assoc, !Z.add_simpl_l.
rewrite ZnZ.spec_zdigits.
rewrite pow2_pos_minus_1 by (red; auto).
apply ZnZ.spec_head0; auto with zarith.
Qed.
Lemma spec_log2 : forall x, [log2 x] = Z.log2 [x].
Proof.
intros. destruct (Z_lt_ge_dec 0 [x]).
symmetry. apply Z.log2_unique. apply spec_pos.
apply spec_log2_pos. intro EQ; rewrite EQ in *; auto with zarith.
rewrite spec_log2_0. rewrite Z.log2_nonpos; auto with zarith.
generalize (spec_pos x); auto with zarith.
Qed.
Lemma log2_digits_head0 : forall x, 0 < [x] ->
[log2 x] = Zpos (digits x) - [head0 x] - 1.
Proof.
intros. rewrite log2_fold.
rewrite spec_eqb. rewrite spec_0.
case Z.eqb_spec.
auto with zarith.
intros _. revert H. rewrite digits_fold, head0_fold. destr_t x as (n,x).
rewrite ZnZ.spec_sub_carry.
intros.
generalize (head0_zdigits n x H).
generalize (ZnZ.spec_to_Z (ZnZ.head0 x)).
generalize (ZnZ.spec_to_Z (ZnZ.zdigits (dom_op n))).
rewrite ZnZ.spec_zdigits. intros. apply Zmod_small.
auto with zarith.
Qed.
(** * Right shift *)
Local Notation shiftrn := (fun n =>
let op := dom_op n in
let zdigits := ZnZ.zdigits op in
let sub_c := ZnZ.sub_c in
let add_mul_div := ZnZ.add_mul_div in
let zzero := ZnZ.zero in
fun x p => match sub_c zdigits p with
| C0 d => reduce n (add_mul_div d zzero x)
| C1 _ => zero
end).
Definition shiftr : t -> t -> t := Eval red_t in
same_level shiftrn.
Lemma shiftr_fold : shiftr = same_level shiftrn.
Proof. red_t; reflexivity. Qed.
Lemma div_pow2_bound :forall x y z,
0 <= x -> 0 <= y -> x < z -> 0 <= x / 2 ^ y < z.
Proof.
intros x y z HH HH1 HH2.
split; auto with zarith.
apply Z.le_lt_trans with (2 := HH2); auto with zarith.
apply Zdiv_le_upper_bound; auto with zarith.
pattern x at 1; replace x with (x * 2 ^ 0); auto with zarith.
apply Z.mul_le_mono_nonneg_l; auto.
apply Z.pow_le_mono_r; auto with zarith.
rewrite Z.pow_0_r; ring.
Qed.
Theorem spec_shiftr_pow2 : forall x n,
[shiftr x n] = [x] / 2 ^ [n].
Proof.
intros x y. rewrite shiftr_fold. apply spec_same_level. clear x y.
intros n x p. simpl.
assert (Hx := ZnZ.spec_to_Z x).
assert (Hy := ZnZ.spec_to_Z p).
generalize (ZnZ.spec_sub_c (ZnZ.zdigits (dom_op n)) p).
case ZnZ.sub_c; intros d H; unfold interp_carry in *; simpl.
(** Subtraction without underflow : [ p <= digits ] *)
rewrite spec_reduce.
rewrite ZnZ.spec_zdigits in H.
rewrite ZnZ.spec_add_mul_div by auto with zarith.
rewrite ZnZ.spec_0, Z.mul_0_l, Z.add_0_l.
rewrite Zmod_small.
f_equal. f_equal. auto with zarith.
split. auto with zarith.
apply div_pow2_bound; auto with zarith.
(** Subtraction with underflow : [ digits < p ] *)
rewrite ZnZ.spec_0. symmetry.
apply Zdiv_small.
split; auto with zarith.
apply Z.lt_le_trans with (base (ZnZ.digits (dom_op n))); auto with zarith.
unfold base. apply Z.pow_le_mono_r; auto with zarith.
rewrite ZnZ.spec_zdigits in H.
generalize (ZnZ.spec_to_Z d); auto with zarith.
Qed.
Lemma spec_shiftr: forall x p, [shiftr x p] = Z.shiftr [x] [p].
Proof.
intros.
now rewrite spec_shiftr_pow2, Z.shiftr_div_pow2 by apply spec_pos.
Qed.
(** * Left shift *)
(** First an unsafe version, working correctly only if
the representation is large enough *)
Local Notation unsafe_shiftln := (fun n =>
let op := dom_op n in
let add_mul_div := ZnZ.add_mul_div in
let zero := ZnZ.zero in
fun x p => reduce n (add_mul_div p x zero)).
Definition unsafe_shiftl : t -> t -> t := Eval red_t in
same_level unsafe_shiftln.
Lemma unsafe_shiftl_fold : unsafe_shiftl = same_level unsafe_shiftln.
Proof. red_t; reflexivity. Qed.
Theorem spec_unsafe_shiftl_aux : forall x p K,
0 <= K ->
[x] < 2^K ->
[p] + K <= Zpos (digits x) ->
[unsafe_shiftl x p] = [x] * 2 ^ [p].
Proof.
intros x p.
rewrite unsafe_shiftl_fold. rewrite digits_level.
apply spec_same_level_dep.
intros n m z z' r LE H K HK H1 H2. apply (H K); auto.
transitivity (Zpos (ZnZ.digits (dom_op n))); auto.
apply digits_dom_op_incr; auto.
clear x p.
intros n x p K HK Hx Hp. simpl. rewrite spec_reduce.
destruct (ZnZ.spec_to_Z x).
destruct (ZnZ.spec_to_Z p).
rewrite ZnZ.spec_add_mul_div by (omega with *).
rewrite ZnZ.spec_0, Zdiv_0_l, Z.add_0_r.
apply Zmod_small. unfold base.
split; auto with zarith.
rewrite Z.mul_comm.
apply Z.lt_le_trans with (2^(ZnZ.to_Z p + K)).
rewrite Zpower_exp; auto with zarith.
apply Z.mul_lt_mono_pos_l; auto with zarith.
apply Z.pow_le_mono_r; auto with zarith.
Qed.
Theorem spec_unsafe_shiftl: forall x p,
[p] <= [head0 x] -> [unsafe_shiftl x p] = [x] * 2 ^ [p].
Proof.
intros.
destruct (Z.eq_dec [x] 0) as [EQ|NEQ].
(* [x] = 0 *)
apply spec_unsafe_shiftl_aux with 0; auto with zarith.
now rewrite EQ.
rewrite spec_head00 in *; auto with zarith.
(* [x] <> 0 *)
apply spec_unsafe_shiftl_aux with ([log2 x] + 1); auto with zarith.
generalize (spec_pos (log2 x)); auto with zarith.
destruct (spec_log2_pos x); auto with zarith.
rewrite log2_digits_head0; auto with zarith.
generalize (spec_pos x); auto with zarith.
Qed.
(** Then we define a function doubling the size of the representation
but without changing the value of the number. *)
Local Notation double_size_n := (fun n =>
let zero := ZnZ.zero in
fun x => mk_t_S n (WW zero x)).
Definition double_size : t -> t := Eval red_t in
iter_t double_size_n.
Lemma double_size_fold : double_size = iter_t double_size_n.
Proof. red_t; reflexivity. Qed.
Lemma double_size_level : forall x, level (double_size x) = S (level x).
Proof.
intros x. rewrite double_size_fold; unfold level at 2. destr_t x as (n,x).
apply mk_t_S_level.
Qed.
Theorem spec_double_size_digits:
forall x, Zpos (digits (double_size x)) = 2 * (Zpos (digits x)).
Proof.
intros x. rewrite ! digits_level, double_size_level.
rewrite 2 digits_dom_op, 2 Pshiftl_nat_Zpower,
Nat2Z.inj_succ, Z.pow_succ_r; auto with zarith.
ring.
Qed.
Theorem spec_double_size: forall x, [double_size x] = [x].
Proof.
intros x. rewrite double_size_fold. destr_t x as (n,x).
rewrite spec_mk_t_S. simpl. rewrite ZnZ.spec_0. auto with zarith.
Qed.
Theorem spec_double_size_head0:
forall x, 2 * [head0 x] <= [head0 (double_size x)].
Proof.
intros x.
assert (F1:= spec_pos (head0 x)).
assert (F2: 0 < Zpos (digits x)).
red; auto.
assert (HH := spec_pos x). Z.le_elim HH.
generalize HH; rewrite <- (spec_double_size x); intros HH1.
case (spec_head0 x HH); intros _ HH2.
case (spec_head0 _ HH1).
rewrite (spec_double_size x); rewrite (spec_double_size_digits x).
intros HH3 _.
case (Z.le_gt_cases ([head0 (double_size x)]) (2 * [head0 x])); auto; intros HH4.
absurd (2 ^ (2 * [head0 x] )* [x] < 2 ^ [head0 (double_size x)] * [x]); auto.
apply Z.le_ngt.
apply Z.mul_le_mono_nonneg_r; auto with zarith.
apply Z.pow_le_mono_r; auto; auto with zarith.
assert (HH5: 2 ^[head0 x] <= 2 ^(Zpos (digits x) - 1)).
{ apply Z.le_succ_l in HH. change (1 <= [x]) in HH.
Z.le_elim HH.
- apply Z.mul_le_mono_pos_r with (2 ^ 1); auto with zarith.
rewrite <- (fun x y z => Z.pow_add_r x (y - z)); auto with zarith.
rewrite Z.sub_add.
apply Z.le_trans with (2 := Z.lt_le_incl _ _ HH2).
apply Z.mul_le_mono_nonneg_l; auto with zarith.
rewrite Z.pow_1_r; auto with zarith.
- apply Z.pow_le_mono_r; auto with zarith.
case (Z.le_gt_cases (Zpos (digits x)) [head0 x]); auto with zarith; intros HH6.
absurd (2 ^ Zpos (digits x) <= 2 ^ [head0 x] * [x]); auto with zarith.
rewrite <- HH; rewrite Z.mul_1_r.
apply Z.pow_le_mono_r; auto with zarith. }
rewrite (Z.mul_comm 2).
rewrite Z.pow_mul_r; auto with zarith.
rewrite Z.pow_2_r.
apply Z.lt_le_trans with (2 := HH3).
rewrite <- Z.mul_assoc.
replace (2 * Zpos (digits x) - 1) with
((Zpos (digits x) - 1) + (Zpos (digits x))).
rewrite Zpower_exp; auto with zarith.
apply Zmult_lt_compat2; auto with zarith.
split; auto with zarith.
apply Z.mul_pos_pos; auto with zarith.
rewrite Pos2Z.inj_xO; ring.
apply Z.lt_le_incl; auto.
repeat rewrite spec_head00; auto.
rewrite spec_double_size_digits.
rewrite Pos2Z.inj_xO; auto with zarith.
rewrite spec_double_size; auto.
Qed.
Theorem spec_double_size_head0_pos:
forall x, 0 < [head0 (double_size x)].
Proof.
intros x.
assert (F := Pos2Z.is_pos (digits x)).
assert (F0 := spec_pos (head0 (double_size x))).
Z.le_elim F0; auto.
assert (F1 := spec_pos (head0 x)).
Z.le_elim F1.
apply Z.lt_le_trans with (2 := (spec_double_size_head0 x)); auto with zarith.
assert (F3 := spec_pos x).
Z.le_elim F3.
generalize F3; rewrite <- (spec_double_size x); intros F4.
absurd (2 ^ (Zpos (xO (digits x)) - 1) < 2 ^ (Zpos (digits x))).
{ apply Z.le_ngt.
apply Z.pow_le_mono_r; auto with zarith.
rewrite Pos2Z.inj_xO; auto with zarith. }
case (spec_head0 x F3).
rewrite <- F1; rewrite Z.pow_0_r; rewrite Z.mul_1_l; intros _ HH.
apply Z.le_lt_trans with (2 := HH).
case (spec_head0 _ F4).
rewrite (spec_double_size x); rewrite (spec_double_size_digits x).
rewrite <- F0; rewrite Z.pow_0_r; rewrite Z.mul_1_l; auto.
generalize F1; rewrite (spec_head00 _ (eq_sym F3)); auto with zarith.
Qed.
(** Finally we iterate [double_size] enough before [unsafe_shiftl]
in order to get a fully correct [shiftl]. *)
Definition shiftl_aux_body cont x n :=
match compare n (head0 x) with
Gt => cont (double_size x) n
| _ => unsafe_shiftl x n
end.
Theorem spec_shiftl_aux_body: forall n x p cont,
2^ Zpos p <= [head0 x] ->
(forall x, 2 ^ (Zpos p + 1) <= [head0 x]->
[cont x n] = [x] * 2 ^ [n]) ->
[shiftl_aux_body cont x n] = [x] * 2 ^ [n].
Proof.
intros n x p cont H1 H2; unfold shiftl_aux_body.
rewrite spec_compare; case Z.compare_spec; intros H.
apply spec_unsafe_shiftl; auto with zarith.
apply spec_unsafe_shiftl; auto with zarith.
rewrite H2.
rewrite spec_double_size; auto.
rewrite Z.add_comm; rewrite Zpower_exp; auto with zarith.
apply Z.le_trans with (2 := spec_double_size_head0 x).
rewrite Z.pow_1_r; apply Z.mul_le_mono_nonneg_l; auto with zarith.
Qed.
Fixpoint shiftl_aux p cont x n :=
shiftl_aux_body
(fun x n => match p with
| xH => cont x n
| xO p => shiftl_aux p (shiftl_aux p cont) x n
| xI p => shiftl_aux p (shiftl_aux p cont) x n
end) x n.
Theorem spec_shiftl_aux: forall p q x n cont,
2 ^ (Zpos q) <= [head0 x] ->
(forall x, 2 ^ (Zpos p + Zpos q) <= [head0 x] ->
[cont x n] = [x] * 2 ^ [n]) ->
[shiftl_aux p cont x n] = [x] * 2 ^ [n].
Proof.
intros p; elim p; unfold shiftl_aux; fold shiftl_aux; clear p.
intros p Hrec q x n cont H1 H2.
apply spec_shiftl_aux_body with (q); auto.
intros x1 H3; apply Hrec with (q + 1)%positive; auto.
intros x2 H4; apply Hrec with (p + q + 1)%positive; auto.
rewrite <- Pos.add_assoc.
rewrite Pos2Z.inj_add; auto.
intros x3 H5; apply H2.
rewrite Pos2Z.inj_xI.
replace (2 * Zpos p + 1 + Zpos q) with (Zpos p + Zpos (p + q + 1));
auto.
rewrite !Pos2Z.inj_add; ring.
intros p Hrec q n x cont H1 H2.
apply spec_shiftl_aux_body with (q); auto.
intros x1 H3; apply Hrec with (q); auto.
apply Z.le_trans with (2 := H3); auto with zarith.
apply Z.pow_le_mono_r; auto with zarith.
intros x2 H4; apply Hrec with (p + q)%positive; auto.
intros x3 H5; apply H2.
rewrite (Pos2Z.inj_xO p).
replace (2 * Zpos p + Zpos q) with (Zpos p + Zpos (p + q));
auto.
rewrite Pos2Z.inj_add; ring.
intros q n x cont H1 H2.
apply spec_shiftl_aux_body with (q); auto.
rewrite Z.add_comm; auto.
Qed.
Definition shiftl x n :=
shiftl_aux_body
(shiftl_aux_body
(shiftl_aux (digits n) unsafe_shiftl)) x n.
Theorem spec_shiftl_pow2 : forall x n,
[shiftl x n] = [x] * 2 ^ [n].
Proof.
intros x n; unfold shiftl, shiftl_aux_body.
rewrite spec_compare; case Z.compare_spec; intros H.
apply spec_unsafe_shiftl; auto with zarith.
apply spec_unsafe_shiftl; auto with zarith.
rewrite <- (spec_double_size x).
rewrite spec_compare; case Z.compare_spec; intros H1.
apply spec_unsafe_shiftl; auto with zarith.
apply spec_unsafe_shiftl; auto with zarith.
rewrite <- (spec_double_size (double_size x)).
apply spec_shiftl_aux with 1%positive.
apply Z.le_trans with (2 := spec_double_size_head0 (double_size x)).
replace (2 ^ 1) with (2 * 1).
apply Z.mul_le_mono_nonneg_l; auto with zarith.
generalize (spec_double_size_head0_pos x); auto with zarith.
rewrite Z.pow_1_r; ring.
intros x1 H2; apply spec_unsafe_shiftl.
apply Z.le_trans with (2 := H2).
apply Z.le_trans with (2 ^ Zpos (digits n)); auto with zarith.
case (spec_digits n); auto with zarith.
apply Z.pow_le_mono_r; auto with zarith.
Qed.
Lemma spec_shiftl: forall x p, [shiftl x p] = Z.shiftl [x] [p].
Proof.
intros.
now rewrite spec_shiftl_pow2, Z.shiftl_mul_pow2 by apply spec_pos.
Qed.
(** Other bitwise operations *)
Definition testbit x n := odd (shiftr x n).
Lemma spec_testbit: forall x p, testbit x p = Z.testbit [x] [p].
Proof.
intros. unfold testbit. symmetry.
rewrite spec_odd, spec_shiftr. apply Z.testbit_odd.
Qed.
Definition div2 x := shiftr x one.
Lemma spec_div2: forall x, [div2 x] = Z.div2 [x].
Proof.
intros. unfold div2. symmetry.
rewrite spec_shiftr, spec_1. apply Z.div2_spec.
Qed.
(** TODO : provide efficient versions instead of just converting
from/to N (see with Laurent) *)
Definition lor x y := of_N (N.lor (to_N x) (to_N y)).
Definition land x y := of_N (N.land (to_N x) (to_N y)).
Definition ldiff x y := of_N (N.ldiff (to_N x) (to_N y)).
Definition lxor x y := of_N (N.lxor (to_N x) (to_N y)).
Lemma spec_land: forall x y, [land x y] = Z.land [x] [y].
Proof.
intros x y. unfold land. rewrite spec_of_N. unfold to_N.
generalize (spec_pos x), (spec_pos y).
destruct [x], [y]; trivial; (now destruct 1) || (now destruct 2).
Qed.
Lemma spec_lor: forall x y, [lor x y] = Z.lor [x] [y].
Proof.
intros x y. unfold lor. rewrite spec_of_N. unfold to_N.
generalize (spec_pos x), (spec_pos y).
destruct [x], [y]; trivial; (now destruct 1) || (now destruct 2).
Qed.
Lemma spec_ldiff: forall x y, [ldiff x y] = Z.ldiff [x] [y].
Proof.
intros x y. unfold ldiff. rewrite spec_of_N. unfold to_N.
generalize (spec_pos x), (spec_pos y).
destruct [x], [y]; trivial; (now destruct 1) || (now destruct 2).
Qed.
Lemma spec_lxor: forall x y, [lxor x y] = Z.lxor [x] [y].
Proof.
intros x y. unfold lxor. rewrite spec_of_N. unfold to_N.
generalize (spec_pos x), (spec_pos y).
destruct [x], [y]; trivial; (now destruct 1) || (now destruct 2).
Qed.
End Make.
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