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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 *)
(************************************************************************)
Require Ring.
Import Ring_polynom Ring_tac Ring_theory InitialRing Setoid List Morphisms.
Require Import ZArith_base.
(*Require Import Omega.*)
Set Implicit Arguments.
Section MakeFieldPol.
(* Field elements *)
Variable R:Type.
Variable (rO rI : R) (radd rmul rsub: R->R->R) (ropp : R->R).
Variable (rdiv : R -> R -> R) (rinv : R -> R).
Variable req : R -> R -> Prop.
Notation "0" := rO. Notation "1" := rI.
Notation "x + y" := (radd x y). Notation "x * y " := (rmul x y).
Notation "x - y " := (rsub x y). Notation "x / y" := (rdiv x y).
Notation "- x" := (ropp x). Notation "/ x" := (rinv x).
Notation "x == y" := (req x y) (at level 70, no associativity).
(* Equality properties *)
Variable Rsth : Equivalence req.
Variable Reqe : ring_eq_ext radd rmul ropp req.
Variable SRinv_ext : forall p q, p == q -> / p == / q.
(* Field properties *)
Record almost_field_theory : Prop := mk_afield {
AF_AR : almost_ring_theory rO rI radd rmul rsub ropp req;
AF_1_neq_0 : ~ 1 == 0;
AFdiv_def : forall p q, p / q == p * / q;
AFinv_l : forall p, ~ p == 0 -> / p * p == 1
}.
Section AlmostField.
Variable AFth : almost_field_theory.
Let ARth := AFth.(AF_AR).
Let rI_neq_rO := AFth.(AF_1_neq_0).
Let rdiv_def := AFth.(AFdiv_def).
Let rinv_l := AFth.(AFinv_l).
(* Coefficients *)
Variable C: Type.
Variable (cO cI: C) (cadd cmul csub : C->C->C) (copp : C->C).
Variable ceqb : C->C->bool.
Variable phi : C -> R.
Variable CRmorph : ring_morph rO rI radd rmul rsub ropp req
cO cI cadd cmul csub copp ceqb phi.
Lemma ceqb_rect : forall c1 c2 (A:Type) (x y:A) (P:A->Type),
(phi c1 == phi c2 -> P x) -> P y -> P (if ceqb c1 c2 then x else y).
Proof.
intros.
generalize (fun h => X (morph_eq CRmorph c1 c2 h)).
case (ceqb c1 c2); auto.
Qed.
(* C notations *)
Notation "x +! y" := (cadd x y) (at level 50).
Notation "x *! y " := (cmul x y) (at level 40).
Notation "x -! y " := (csub x y) (at level 50).
Notation "-! x" := (copp x) (at level 35).
Notation " x ?=! y" := (ceqb x y) (at level 70, no associativity).
Notation "[ x ]" := (phi x) (at level 0).
(* Useful tactics *)
Add Morphism radd : radd_ext. exact (Radd_ext Reqe). Qed.
Add Morphism rmul : rmul_ext. exact (Rmul_ext Reqe). Qed.
Add Morphism ropp : ropp_ext. exact (Ropp_ext Reqe). Qed.
Add Morphism rsub : rsub_ext. exact (ARsub_ext Rsth Reqe ARth). Qed.
Add Morphism rinv : rinv_ext. exact SRinv_ext. Qed.
Let eq_trans := Setoid.Seq_trans _ _ Rsth.
Let eq_sym := Setoid.Seq_sym _ _ Rsth.
Let eq_refl := Setoid.Seq_refl _ _ Rsth.
Hint Resolve eq_refl rdiv_def rinv_l rI_neq_rO CRmorph.(morph1) .
Hint Resolve (Rmul_ext Reqe) (Rmul_ext Reqe) (Radd_ext Reqe)
(ARsub_ext Rsth Reqe ARth) (Ropp_ext Reqe) SRinv_ext.
Hint Resolve (ARadd_0_l ARth) (ARadd_comm ARth) (ARadd_assoc ARth)
(ARmul_1_l ARth) (ARmul_0_l ARth)
(ARmul_comm ARth) (ARmul_assoc ARth) (ARdistr_l ARth)
(ARopp_mul_l ARth) (ARopp_add ARth)
(ARsub_def ARth) .
(* Power coefficients *)
Variable Cpow : Type.
Variable Cp_phi : N -> Cpow.
Variable rpow : R -> Cpow -> R.
Variable pow_th : power_theory rI rmul req Cp_phi rpow.
(* sign function *)
Variable get_sign : C -> option C.
Variable get_sign_spec : sign_theory copp ceqb get_sign.
Variable cdiv:C -> C -> C*C.
Variable cdiv_th : div_theory req cadd cmul phi cdiv.
Notation NPEeval := (PEeval rO radd rmul rsub ropp phi Cp_phi rpow).
Notation Nnorm:= (norm_subst cO cI cadd cmul csub copp ceqb cdiv).
Notation NPphi_dev := (Pphi_dev rO rI radd rmul rsub ropp cO cI ceqb phi get_sign).
Notation NPphi_pow := (Pphi_pow rO rI radd rmul rsub ropp cO cI ceqb phi Cp_phi rpow get_sign).
(* add abstract semi-ring to help with some proofs *)
Add Ring Rring : (ARth_SRth ARth).
Local Hint Extern 2 (_ == _) => f_equiv.
(* additional ring properties *)
Lemma rsub_0_l : forall r, 0 - r == - r.
intros; rewrite (ARsub_def ARth);ring.
Qed.
Lemma rsub_0_r : forall r, r - 0 == r.
intros; rewrite (ARsub_def ARth).
rewrite (ARopp_zero Rsth Reqe ARth); ring.
Qed.
(***************************************************************************
Properties of division
***************************************************************************)
Theorem rdiv_simpl: forall p q, ~ q == 0 -> q * (p / q) == p.
Proof.
intros p q H.
rewrite rdiv_def.
transitivity (/ q * q * p); [ ring | idtac ].
rewrite rinv_l; auto.
Qed.
Hint Resolve rdiv_simpl .
Instance SRdiv_ext: Proper (req ==> req ==> req) rdiv.
Proof.
intros p1 p2 Ep q1 q2 Eq.
transitivity (p1 * / q1); auto.
transitivity (p2 * / q2); auto.
Qed.
Hint Resolve SRdiv_ext.
Lemma rmul_reg_l : forall p q1 q2,
~ p == 0 -> p * q1 == p * q2 -> q1 == q2.
Proof.
intros p q1 q2 H EQ.
rewrite <- (@rdiv_simpl q1 p) by trivial.
rewrite <- (@rdiv_simpl q2 p) by trivial.
rewrite !rdiv_def, !(ARmul_assoc ARth).
now rewrite EQ.
Qed.
Theorem field_is_integral_domain : forall r1 r2,
~ r1 == 0 -> ~ r2 == 0 -> ~ r1 * r2 == 0.
Proof.
intros r1 r2 H1 H2. contradict H2.
transitivity (1 * r2); auto.
transitivity (/ r1 * r1 * r2); auto.
rewrite <- (ARmul_assoc ARth).
rewrite H2.
apply ARmul_0_r with (1 := Rsth) (2 := ARth).
Qed.
Theorem ropp_neq_0 : forall r,
~ -(1) == 0 -> ~ r == 0 -> ~ -r == 0.
intros.
setoid_replace (- r) with (- (1) * r).
apply field_is_integral_domain; trivial.
rewrite <- (ARopp_mul_l ARth).
rewrite (ARmul_1_l ARth).
reflexivity.
Qed.
Theorem rdiv_r_r : forall r, ~ r == 0 -> r / r == 1.
intros.
rewrite (AFdiv_def AFth).
rewrite (ARmul_comm ARth).
apply (AFinv_l AFth).
trivial.
Qed.
Theorem rdiv1: forall r, r == r / 1.
intros r; transitivity (1 * (r / 1)); auto.
Qed.
Theorem rdiv2:
forall r1 r2 r3 r4,
~ r2 == 0 ->
~ r4 == 0 ->
r1 / r2 + r3 / r4 == (r1 * r4 + r3 * r2) / (r2 * r4).
Proof.
intros r1 r2 r3 r4 H H0.
assert (~ r2 * r4 == 0) by (apply field_is_integral_domain; trivial).
apply rmul_reg_l with (r2 * r4); trivial.
rewrite rdiv_simpl; trivial.
rewrite (ARdistr_r Rsth Reqe ARth).
apply (Radd_ext Reqe).
- transitivity (r2 * (r1 / r2) * r4); [ ring | auto ].
- transitivity (r2 * (r4 * (r3 / r4))); auto.
transitivity (r2 * r3); auto.
Qed.
Theorem rdiv2b:
forall r1 r2 r3 r4 r5,
~ (r2*r5) == 0 ->
~ (r4*r5) == 0 ->
r1 / (r2*r5) + r3 / (r4*r5) == (r1 * r4 + r3 * r2) / (r2 * (r4 * r5)).
Proof.
intros r1 r2 r3 r4 r5 H H0.
assert (HH1: ~ r2 == 0) by (intros HH; case H; rewrite HH; ring).
assert (HH2: ~ r5 == 0) by (intros HH; case H; rewrite HH; ring).
assert (HH3: ~ r4 == 0) by (intros HH; case H0; rewrite HH; ring).
assert (HH4: ~ r2 * (r4 * r5) == 0)
by (repeat apply field_is_integral_domain; trivial).
apply rmul_reg_l with (r2 * (r4 * r5)); trivial.
rewrite rdiv_simpl; trivial.
rewrite (ARdistr_r Rsth Reqe ARth).
apply (Radd_ext Reqe).
transitivity ((r2 * r5) * (r1 / (r2 * r5)) * r4); [ ring | auto ].
transitivity ((r4 * r5) * (r3 / (r4 * r5)) * r2); [ ring | auto ].
Qed.
Theorem rdiv5: forall r1 r2, - (r1 / r2) == - r1 / r2.
Proof.
intros r1 r2.
transitivity (- (r1 * / r2)); auto.
transitivity (- r1 * / r2); auto.
Qed.
Hint Resolve rdiv5 .
Theorem rdiv3 r1 r2 r3 r4 :
~ r2 == 0 ->
~ r4 == 0 ->
r1 / r2 - r3 / r4 == (r1 * r4 - r3 * r2) / (r2 * r4).
Proof.
intros H2 H4.
assert (~ r2 * r4 == 0) by (apply field_is_integral_domain; trivial).
transitivity (r1 / r2 + - (r3 / r4)); auto.
transitivity (r1 / r2 + - r3 / r4); auto.
transitivity ((r1 * r4 + - r3 * r2) / (r2 * r4)).
apply rdiv2; auto.
f_equiv.
transitivity (r1 * r4 + - (r3 * r2)); auto.
Qed.
Theorem rdiv3b:
forall r1 r2 r3 r4 r5,
~ (r2 * r5) == 0 ->
~ (r4 * r5) == 0 ->
r1 / (r2*r5) - r3 / (r4*r5) == (r1 * r4 - r3 * r2) / (r2 * (r4 * r5)).
Proof.
intros r1 r2 r3 r4 r5 H H0.
transitivity (r1 / (r2 * r5) + - (r3 / (r4 * r5))); auto.
transitivity (r1 / (r2 * r5) + - r3 / (r4 * r5)); auto.
transitivity ((r1 * r4 + - r3 * r2) / (r2 * (r4 * r5))).
apply rdiv2b; auto; try ring.
apply (SRdiv_ext); auto.
transitivity (r1 * r4 + - (r3 * r2)); symmetry; auto.
Qed.
Theorem rdiv6:
forall r1 r2,
~ r1 == 0 -> ~ r2 == 0 -> / (r1 / r2) == r2 / r1.
intros r1 r2 H H0.
assert (~ r1 / r2 == 0) as Hk.
intros H1; case H.
transitivity (r2 * (r1 / r2)); auto.
rewrite H1; ring.
apply rmul_reg_l with (r1 / r2); auto.
transitivity (/ (r1 / r2) * (r1 / r2)); auto.
transitivity 1; auto.
repeat rewrite rdiv_def.
transitivity (/ r1 * r1 * (/ r2 * r2)); [ idtac | ring ].
repeat rewrite rinv_l; auto.
Qed.
Hint Resolve rdiv6 .
Theorem rdiv4:
forall r1 r2 r3 r4,
~ r2 == 0 ->
~ r4 == 0 ->
(r1 / r2) * (r3 / r4) == (r1 * r3) / (r2 * r4).
Proof.
intros r1 r2 r3 r4 H H0.
assert (~ r2 * r4 == 0) by (apply field_is_integral_domain; trivial).
apply rmul_reg_l with (r2 * r4); trivial.
rewrite rdiv_simpl; trivial.
transitivity (r2 * (r1 / r2) * (r4 * (r3 / r4))); [ ring | idtac ].
repeat rewrite rdiv_simpl; trivial.
Qed.
Theorem rdiv4b:
forall r1 r2 r3 r4 r5 r6,
~ r2 * r5 == 0 ->
~ r4 * r6 == 0 ->
((r1 * r6) / (r2 * r5)) * ((r3 * r5) / (r4 * r6)) == (r1 * r3) / (r2 * r4).
Proof.
intros r1 r2 r3 r4 r5 r6 H H0.
rewrite rdiv4; auto.
transitivity ((r5 * r6) * (r1 * r3) / ((r5 * r6) * (r2 * r4))).
apply SRdiv_ext; ring.
assert (HH: ~ r5*r6 == 0).
apply field_is_integral_domain.
intros H1; case H; rewrite H1; ring.
intros H1; case H0; rewrite H1; ring.
rewrite <- rdiv4 ; auto.
rewrite rdiv_r_r; auto.
apply field_is_integral_domain.
intros H1; case H; rewrite H1; ring.
intros H1; case H0; rewrite H1; ring.
Qed.
Theorem rdiv7:
forall r1 r2 r3 r4,
~ r2 == 0 ->
~ r3 == 0 ->
~ r4 == 0 ->
(r1 / r2) / (r3 / r4) == (r1 * r4) / (r2 * r3).
Proof.
intros.
rewrite (rdiv_def (r1 / r2)).
rewrite rdiv6; trivial.
apply rdiv4; trivial.
Qed.
Theorem rdiv7b:
forall r1 r2 r3 r4 r5 r6,
~ r2 * r6 == 0 ->
~ r3 * r5 == 0 ->
~ r4 * r6 == 0 ->
((r1 * r5) / (r2 * r6)) / ((r3 * r5) / (r4 * r6)) == (r1 * r4) / (r2 * r3).
Proof.
intros.
rewrite rdiv7; auto.
transitivity ((r5 * r6) * (r1 * r4) / ((r5 * r6) * (r2 * r3))).
apply SRdiv_ext; ring.
assert (HH: ~ r5*r6 == 0).
apply field_is_integral_domain.
intros H2; case H0; rewrite H2; ring.
intros H2; case H1; rewrite H2; ring.
rewrite <- rdiv4 ; auto.
rewrite rdiv_r_r; auto.
apply field_is_integral_domain.
intros H2; case H; rewrite H2; ring.
intros H2; case H0; rewrite H2; ring.
Qed.
Theorem rdiv8: forall r1 r2, ~ r2 == 0 -> r1 == 0 -> r1 / r2 == 0.
intros r1 r2 H H0.
transitivity (r1 * / r2); auto.
transitivity (0 * / r2); auto.
Qed.
Theorem cross_product_eq : forall r1 r2 r3 r4,
~ r2 == 0 -> ~ r4 == 0 -> r1 * r4 == r3 * r2 -> r1 / r2 == r3 / r4.
intros.
transitivity (r1 / r2 * (r4 / r4)).
rewrite rdiv_r_r; trivial.
symmetry .
apply (ARmul_1_r Rsth ARth).
rewrite rdiv4; trivial.
rewrite H1.
rewrite (ARmul_comm ARth r2 r4).
rewrite <- rdiv4; trivial.
rewrite rdiv_r_r by trivial.
apply (ARmul_1_r Rsth ARth).
Qed.
(***************************************************************************
Some equality test
***************************************************************************)
(* equality test *)
Fixpoint PExpr_eq (e1 e2 : PExpr C) {struct e1} : bool :=
match e1, e2 with
PEc c1, PEc c2 => ceqb c1 c2
| PEX p1, PEX p2 => Pos.eqb p1 p2
| PEadd e3 e5, PEadd e4 e6 => if PExpr_eq e3 e4 then PExpr_eq e5 e6 else false
| PEsub e3 e5, PEsub e4 e6 => if PExpr_eq e3 e4 then PExpr_eq e5 e6 else false
| PEmul e3 e5, PEmul e4 e6 => if PExpr_eq e3 e4 then PExpr_eq e5 e6 else false
| PEopp e3, PEopp e4 => PExpr_eq e3 e4
| PEpow e3 n3, PEpow e4 n4 => if N.eqb n3 n4 then PExpr_eq e3 e4 else false
| _, _ => false
end.
Add Morphism (pow_pos rmul) with signature req ==> eq ==> req as pow_morph.
intros x y H p;induction p as [p IH| p IH|];simpl;auto;ring[IH].
Qed.
Add Morphism (pow_N rI rmul) with signature req ==> eq ==> req as pow_N_morph.
intros x y H [|p];simpl;auto. apply pow_morph;trivial.
Qed.
Theorem PExpr_eq_semi_correct:
forall l e1 e2, PExpr_eq e1 e2 = true -> NPEeval l e1 == NPEeval l e2.
intros l e1; elim e1.
intros c1; intros e2; elim e2; simpl; (try (intros; discriminate)).
intros c2; apply (morph_eq CRmorph).
intros p1; intros e2; elim e2; simpl; (try (intros; discriminate)).
intros p2; case Pos.eqb_spec; intros; now subst.
intros e3 rec1 e5 rec2 e2; case e2; simpl; (try (intros; discriminate)).
intros e4 e6; generalize (rec1 e4); case (PExpr_eq e3 e4);
(try (intros; discriminate)); generalize (rec2 e6); case (PExpr_eq e5 e6);
(try (intros; discriminate)); auto.
intros e3 rec1 e5 rec2 e2; case e2; simpl; (try (intros; discriminate)).
intros e4 e6; generalize (rec1 e4); case (PExpr_eq e3 e4);
(try (intros; discriminate)); generalize (rec2 e6); case (PExpr_eq e5 e6);
(try (intros; discriminate)); auto.
intros e3 rec1 e5 rec2 e2; case e2; simpl; (try (intros; discriminate)).
intros e4 e6; generalize (rec1 e4); case (PExpr_eq e3 e4);
(try (intros; discriminate)); generalize (rec2 e6); case (PExpr_eq e5 e6);
(try (intros; discriminate)); auto.
intros e3 rec e2; (case e2; simpl; (try (intros; discriminate))).
intros e4; generalize (rec e4); case (PExpr_eq e3 e4);
(try (intros; discriminate)); auto.
intros e3 rec n3 e2;(case e2;simpl;(try (intros;discriminate))).
intros e4 n4; case N.eqb_spec; try discriminate; intros EQ H; subst.
repeat rewrite pow_th.(rpow_pow_N). rewrite (rec _ H);auto.
Qed.
(* add *)
Definition NPEadd e1 e2 :=
match e1, e2 with
PEc c1, PEc c2 => PEc (cadd c1 c2)
| PEc c, _ => if ceqb c cO then e2 else PEadd e1 e2
| _, PEc c => if ceqb c cO then e1 else PEadd e1 e2
(* Peut t'on factoriser ici ??? *)
| _, _ => PEadd e1 e2
end.
Theorem NPEadd_correct:
forall l e1 e2, NPEeval l (NPEadd e1 e2) == NPEeval l (PEadd e1 e2).
Proof.
intros l e1 e2.
destruct e1; destruct e2; simpl; try reflexivity; try apply ceqb_rect;
try (intro eq_c; rewrite eq_c); simpl;try apply eq_refl;
try (ring [(morph0 CRmorph)]).
apply (morph_add CRmorph).
Qed.
Definition NPEpow x n :=
match n with
| N0 => PEc cI
| Npos p =>
if Pos.eqb p xH then x else
match x with
| PEc c =>
if ceqb c cI then PEc cI else if ceqb c cO then PEc cO else PEc (pow_pos cmul c p)
| _ => PEpow x n
end
end.
Theorem NPEpow_correct : forall l e n,
NPEeval l (NPEpow e n) == NPEeval l (PEpow e n).
Proof.
destruct n;simpl.
rewrite pow_th.(rpow_pow_N);simpl;auto.
fold (p =? 1)%positive.
case Pos.eqb_spec; intros H; (rewrite H || clear H).
now rewrite pow_th.(rpow_pow_N).
destruct e;simpl;auto.
repeat apply ceqb_rect;simpl;intros;rewrite pow_th.(rpow_pow_N);simpl.
symmetry;induction p;simpl;trivial; ring [IHp H CRmorph.(morph1)].
symmetry; induction p;simpl;trivial;ring [IHp CRmorph.(morph0)].
induction p;simpl;auto;repeat rewrite CRmorph.(morph_mul);ring [IHp].
Qed.
(* mul *)
Fixpoint NPEmul (x y : PExpr C) {struct x} : PExpr C :=
match x, y with
PEc c1, PEc c2 => PEc (cmul c1 c2)
| PEc c, _ =>
if ceqb c cI then y else if ceqb c cO then PEc cO else PEmul x y
| _, PEc c =>
if ceqb c cI then x else if ceqb c cO then PEc cO else PEmul x y
| PEpow e1 n1, PEpow e2 n2 =>
if N.eqb n1 n2 then NPEpow (NPEmul e1 e2) n1 else PEmul x y
| _, _ => PEmul x y
end.
Lemma pow_pos_mul : forall x y p, pow_pos rmul (x * y) p == pow_pos rmul x p * pow_pos rmul y p.
induction p;simpl;auto;try ring [IHp].
Qed.
Theorem NPEmul_correct : forall l e1 e2,
NPEeval l (NPEmul e1 e2) == NPEeval l (PEmul e1 e2).
induction e1;destruct e2; simpl;try reflexivity;
repeat apply ceqb_rect;
try (intro eq_c; rewrite eq_c); simpl; try reflexivity;
try ring [(morph0 CRmorph) (morph1 CRmorph)].
apply (morph_mul CRmorph).
case N.eqb_spec; intros H; try rewrite <- H; clear H.
rewrite NPEpow_correct. simpl.
repeat rewrite pow_th.(rpow_pow_N).
rewrite IHe1; destruct n;simpl;try ring.
apply pow_pos_mul.
simpl;auto.
Qed.
(* sub *)
Definition NPEsub e1 e2 :=
match e1, e2 with
PEc c1, PEc c2 => PEc (csub c1 c2)
| PEc c, _ => if ceqb c cO then PEopp e2 else PEsub e1 e2
| _, PEc c => if ceqb c cO then e1 else PEsub e1 e2
(* Peut-on factoriser ici *)
| _, _ => PEsub e1 e2
end.
Theorem NPEsub_correct:
forall l e1 e2, NPEeval l (NPEsub e1 e2) == NPEeval l (PEsub e1 e2).
intros l e1 e2.
destruct e1; destruct e2; simpl; try reflexivity; try apply ceqb_rect;
try (intro eq_c; rewrite eq_c); simpl;
try rewrite (morph0 CRmorph); try reflexivity;
try (symmetry; apply rsub_0_l); try (symmetry; apply rsub_0_r).
apply (morph_sub CRmorph).
Qed.
(* opp *)
Definition NPEopp e1 :=
match e1 with PEc c1 => PEc (copp c1) | _ => PEopp e1 end.
Theorem NPEopp_correct:
forall l e1, NPEeval l (NPEopp e1) == NPEeval l (PEopp e1).
intros l e1; case e1; simpl; auto.
intros; apply (morph_opp CRmorph).
Qed.
(* simplification *)
Fixpoint PExpr_simp (e : PExpr C) : PExpr C :=
match e with
PEadd e1 e2 => NPEadd (PExpr_simp e1) (PExpr_simp e2)
| PEmul e1 e2 => NPEmul (PExpr_simp e1) (PExpr_simp e2)
| PEsub e1 e2 => NPEsub (PExpr_simp e1) (PExpr_simp e2)
| PEopp e1 => NPEopp (PExpr_simp e1)
| PEpow e1 n1 => NPEpow (PExpr_simp e1) n1
| _ => e
end.
Theorem PExpr_simp_correct:
forall l e, NPEeval l (PExpr_simp e) == NPEeval l e.
intros l e; elim e; simpl; auto.
intros e1 He1 e2 He2.
transitivity (NPEeval l (PEadd (PExpr_simp e1) (PExpr_simp e2))); auto.
apply NPEadd_correct.
simpl; auto.
intros e1 He1 e2 He2.
transitivity (NPEeval l (PEsub (PExpr_simp e1) (PExpr_simp e2))); auto.
apply NPEsub_correct.
simpl; auto.
intros e1 He1 e2 He2.
transitivity (NPEeval l (PEmul (PExpr_simp e1) (PExpr_simp e2))); auto.
apply NPEmul_correct.
simpl; auto.
intros e1 He1.
transitivity (NPEeval l (PEopp (PExpr_simp e1))); auto.
apply NPEopp_correct.
simpl; auto.
intros e1 He1 n;simpl.
rewrite NPEpow_correct;simpl.
repeat rewrite pow_th.(rpow_pow_N).
rewrite He1;auto.
Qed.
(****************************************************************************
Datastructure
***************************************************************************)
(* The input: syntax of a field expression *)
Inductive FExpr : Type :=
FEc: C -> FExpr
| FEX: positive -> FExpr
| FEadd: FExpr -> FExpr -> FExpr
| FEsub: FExpr -> FExpr -> FExpr
| FEmul: FExpr -> FExpr -> FExpr
| FEopp: FExpr -> FExpr
| FEinv: FExpr -> FExpr
| FEdiv: FExpr -> FExpr -> FExpr
| FEpow: FExpr -> N -> FExpr .
Fixpoint FEeval (l : list R) (pe : FExpr) {struct pe} : R :=
match pe with
| FEc c => phi c
| FEX x => BinList.nth 0 x l
| FEadd x y => FEeval l x + FEeval l y
| FEsub x y => FEeval l x - FEeval l y
| FEmul x y => FEeval l x * FEeval l y
| FEopp x => - FEeval l x
| FEinv x => / FEeval l x
| FEdiv x y => FEeval l x / FEeval l y
| FEpow x n => rpow (FEeval l x) (Cp_phi n)
end.
Strategy expand [FEeval].
(* The result of the normalisation *)
Record linear : Type := mk_linear {
num : PExpr C;
denum : PExpr C;
condition : list (PExpr C) }.
(***************************************************************************
Semantics and properties of side condition
***************************************************************************)
Fixpoint PCond (l : list R) (le : list (PExpr C)) {struct le} : Prop :=
match le with
| nil => True
| e1 :: nil => ~ req (NPEeval l e1) rO
| e1 :: l1 => ~ req (NPEeval l e1) rO /\ PCond l l1
end.
Theorem PCond_cons_inv_l :
forall l a l1, PCond l (a::l1) -> ~ NPEeval l a == 0.
intros l a l1 H.
destruct l1; simpl in H |- *; trivial.
destruct H; trivial.
Qed.
Theorem PCond_cons_inv_r : forall l a l1, PCond l (a :: l1) -> PCond l l1.
intros l a l1 H.
destruct l1; simpl in H |- *; trivial.
destruct H; trivial.
Qed.
Theorem PCond_app_inv_l: forall l l1 l2, PCond l (l1 ++ l2) -> PCond l l1.
intros l l1 l2; elim l1; simpl app.
simpl; auto.
destruct l0; simpl in *.
destruct l2; firstorder.
firstorder.
Qed.
Theorem PCond_app_inv_r: forall l l1 l2, PCond l (l1 ++ l2) -> PCond l l2.
intros l l1 l2; elim l1; simpl app; auto.
intros a l0 H H0; apply H; apply PCond_cons_inv_r with ( 1 := H0 ).
Qed.
(* An unsatisfiable condition: issued when a division by zero is detected *)
Definition absurd_PCond := cons (PEc cO) nil.
Lemma absurd_PCond_bottom : forall l, ~ PCond l absurd_PCond.
unfold absurd_PCond; simpl.
red; intros.
apply H.
apply (morph0 CRmorph).
Qed.
(***************************************************************************
Normalisation
***************************************************************************)
Fixpoint isIn (e1:PExpr C) (p1:positive)
(e2:PExpr C) (p2:positive) {struct e2}: option (N * PExpr C) :=
match e2 with
| PEmul e3 e4 =>
match isIn e1 p1 e3 p2 with
| Some (N0, e5) => Some (N0, NPEmul e5 (NPEpow e4 (Npos p2)))
| Some (Npos p, e5) =>
match isIn e1 p e4 p2 with
| Some (n, e6) => Some (n, NPEmul e5 e6)
| None => Some (Npos p, NPEmul e5 (NPEpow e4 (Npos p2)))
end
| None =>
match isIn e1 p1 e4 p2 with
| Some (n, e5) => Some (n,NPEmul (NPEpow e3 (Npos p2)) e5)
| None => None
end
end
| PEpow e3 N0 => None
| PEpow e3 (Npos p3) => isIn e1 p1 e3 (Pos.mul p3 p2)
| _ =>
if PExpr_eq e1 e2 then
match Z.pos_sub p1 p2 with
| Zpos p => Some (Npos p, PEc cI)
| Z0 => Some (N0, PEc cI)
| Zneg p => Some (N0, NPEpow e2 (Npos p))
end
else None
end.
Definition ZtoN z := match z with Zpos p => Npos p | _ => N0 end.
Definition NtoZ n := match n with Npos p => Zpos p | _ => Z0 end.
Notation pow_pos_add :=
(Ring_theory.pow_pos_add Rsth Reqe.(Rmul_ext) ARth.(ARmul_assoc)).
Lemma Z_pos_sub_gt p q : (p > q)%positive ->
Z.pos_sub p q = Zpos (p - q).
Proof. intros; now apply Z.pos_sub_gt, Pos.gt_lt. Qed.
Ltac simpl_pos_sub := rewrite ?Z_pos_sub_gt in * by assumption.
Lemma isIn_correct_aux : forall l e1 e2 p1 p2,
match
(if PExpr_eq e1 e2 then
match Z.sub (Zpos p1) (Zpos p2) with
| Zpos p => Some (Npos p, PEc cI)
| Z0 => Some (N0, PEc cI)
| Zneg p => Some (N0, NPEpow e2 (Npos p))
end
else None)
with
| Some(n, e3) =>
NPEeval l (PEpow e2 (Npos p2)) ==
NPEeval l (PEmul (PEpow e1 (ZtoN (Zpos p1 - NtoZ n))) e3) /\
(Zpos p1 > NtoZ n)%Z
| _ => True
end.
Proof.
intros l e1 e2 p1 p2; generalize (PExpr_eq_semi_correct l e1 e2);
case (PExpr_eq e1 e2); simpl; auto; intros H.
rewrite Z.pos_sub_spec.
case Pos.compare_spec;intros;simpl.
- repeat rewrite pow_th.(rpow_pow_N);simpl. split. 2:reflexivity.
subst. rewrite H by trivial. ring [ (morph1 CRmorph)].
- fold (p2 - p1 =? 1)%positive.
fold (NPEpow e2 (Npos (p2 - p1))).
rewrite NPEpow_correct;simpl.
repeat rewrite pow_th.(rpow_pow_N);simpl.
rewrite H;trivial. split. 2:reflexivity.
rewrite <- pow_pos_add. now rewrite Pos.add_comm, Pos.sub_add.
- repeat rewrite pow_th.(rpow_pow_N);simpl.
rewrite H;trivial.
rewrite Z.pos_sub_gt by now apply Pos.sub_decr.
replace (p1 - (p1 - p2))%positive with p2;
[| rewrite Pos.sub_sub_distr, Pos.add_comm;
auto using Pos.add_sub, Pos.sub_decr ].
split.
simpl. ring [ (morph1 CRmorph)].
now apply Z.lt_gt, Pos.sub_decr.
Qed.
Lemma pow_pos_pow_pos : forall x p1 p2, pow_pos rmul (pow_pos rmul x p1) p2 == pow_pos rmul x (p1*p2).
induction p1;simpl;intros;repeat rewrite pow_pos_mul;repeat rewrite pow_pos_add;simpl.
ring [(IHp1 p2)]. ring [(IHp1 p2)]. auto.
Qed.
Theorem isIn_correct: forall l e1 p1 e2 p2,
match isIn e1 p1 e2 p2 with
| Some(n, e3) =>
NPEeval l (PEpow e2 (Npos p2)) ==
NPEeval l (PEmul (PEpow e1 (ZtoN (Zpos p1 - NtoZ n))) e3) /\
(Zpos p1 > NtoZ n)%Z
| _ => True
end.
Proof.
Opaque NPEpow.
intros l e1 p1 e2; generalize p1;clear p1;elim e2; intros;
try (refine (isIn_correct_aux l e1 _ p1 p2);fail);simpl isIn.
generalize (H p1 p2);clear H;destruct (isIn e1 p1 p p2). destruct p3.
destruct n.
simpl. rewrite NPEmul_correct. simpl; rewrite NPEpow_correct;simpl.
repeat rewrite pow_th.(rpow_pow_N);simpl.
rewrite pow_pos_mul;intros (H,H1);split;[ring[H]|trivial].
generalize (H0 p4 p2);clear H0;destruct (isIn e1 p4 p0 p2). destruct p5.
destruct n;simpl.
rewrite NPEmul_correct;repeat rewrite pow_th.(rpow_pow_N);simpl.
intros (H1,H2) (H3,H4).
simpl_pos_sub. simpl in H3.
rewrite pow_pos_mul. rewrite H1;rewrite H3.
assert (pow_pos rmul (NPEeval l e1) (p1 - p4) * NPEeval l p3 *
(pow_pos rmul (NPEeval l e1) p4 * NPEeval l p5) ==
pow_pos rmul (NPEeval l e1) p4 * pow_pos rmul (NPEeval l e1) (p1 - p4) *
NPEeval l p3 *NPEeval l p5) by ring. rewrite H;clear H.
rewrite <- pow_pos_add.
rewrite Pos.add_comm, Pos.sub_add by (now apply Z.gt_lt in H4).
split. symmetry;apply ARth.(ARmul_assoc). reflexivity.
repeat rewrite pow_th.(rpow_pow_N);simpl.
intros (H1,H2) (H3,H4).
simpl_pos_sub. simpl in H1, H3.
assert (Zpos p1 > Zpos p6)%Z.
apply Zgt_trans with (Zpos p4). exact H4. exact H2.
simpl_pos_sub.
split. 2:exact H.
rewrite pow_pos_mul. simpl;rewrite H1;rewrite H3.
assert (pow_pos rmul (NPEeval l e1) (p1 - p4) * NPEeval l p3 *
(pow_pos rmul (NPEeval l e1) (p4 - p6) * NPEeval l p5) ==
pow_pos rmul (NPEeval l e1) (p1 - p4) * pow_pos rmul (NPEeval l e1) (p4 - p6) *
NPEeval l p3 * NPEeval l p5) by ring. rewrite H0;clear H0.
rewrite <- pow_pos_add.
replace (p1 - p4 + (p4 - p6))%positive with (p1 - p6)%positive.
rewrite NPEmul_correct. simpl;ring.
assert
(Zpos p1 - Zpos p6 = Zpos p1 - Zpos p4 + (Zpos p4 - Zpos p6))%Z.
change ((Zpos p1 - Zpos p6)%Z = (Zpos p1 + (- Zpos p4) + (Zpos p4 +(- Zpos p6)))%Z).
rewrite <- Z.add_assoc. rewrite (Z.add_assoc (- Zpos p4)).
simpl. rewrite Z.pos_sub_diag. simpl. reflexivity.
unfold Z.sub, Z.opp in H0. simpl in H0.
simpl_pos_sub. inversion H0; trivial.
simpl. repeat rewrite pow_th.(rpow_pow_N).
intros H1 (H2,H3). simpl_pos_sub.
rewrite NPEmul_correct;simpl;rewrite NPEpow_correct;simpl.
simpl in H2. rewrite pow_th.(rpow_pow_N);simpl.
rewrite pow_pos_mul. split. ring [H2]. exact H3.
generalize (H0 p1 p2);clear H0;destruct (isIn e1 p1 p0 p2). destruct p3.
destruct n;simpl. rewrite NPEmul_correct;simpl;rewrite NPEpow_correct;simpl.
repeat rewrite pow_th.(rpow_pow_N);simpl.
intros (H1,H2);split;trivial. rewrite pow_pos_mul;ring [H1].
rewrite NPEmul_correct;simpl;rewrite NPEpow_correct;simpl.
repeat rewrite pow_th.(rpow_pow_N);simpl. rewrite pow_pos_mul.
intros (H1, H2);rewrite H1;split.
simpl_pos_sub. simpl in H1;ring [H1]. trivial.
trivial.
destruct n. trivial.
generalize (H p1 (p0*p2)%positive);clear H;destruct (isIn e1 p1 p (p0*p2)). destruct p3.
destruct n;simpl. repeat rewrite pow_th.(rpow_pow_N). simpl.
intros (H1,H2);split. rewrite pow_pos_pow_pos. trivial. trivial.
repeat rewrite pow_th.(rpow_pow_N). simpl.
intros (H1,H2);split;trivial.
rewrite pow_pos_pow_pos;trivial.
trivial.
Qed.
Record rsplit : Type := mk_rsplit {
rsplit_left : PExpr C;
rsplit_common : PExpr C;
rsplit_right : PExpr C}.
(* Stupid name clash *)
Notation left := rsplit_left.
Notation right := rsplit_right.
Notation common := rsplit_common.
Fixpoint split_aux (e1: PExpr C) (p:positive) (e2:PExpr C) {struct e1}: rsplit :=
match e1 with
| PEmul e3 e4 =>
let r1 := split_aux e3 p e2 in
let r2 := split_aux e4 p (right r1) in
mk_rsplit (NPEmul (left r1) (left r2))
(NPEmul (common r1) (common r2))
(right r2)
| PEpow e3 N0 => mk_rsplit (PEc cI) (PEc cI) e2
| PEpow e3 (Npos p3) => split_aux e3 (Pos.mul p3 p) e2
| _ =>
match isIn e1 p e2 xH with
| Some (N0,e3) => mk_rsplit (PEc cI) (NPEpow e1 (Npos p)) e3
| Some (Npos q, e3) => mk_rsplit (NPEpow e1 (Npos q)) (NPEpow e1 (Npos (p - q))) e3
| None => mk_rsplit (NPEpow e1 (Npos p)) (PEc cI) e2
end
end.
Lemma split_aux_correct_1 : forall l e1 p e2,
let res := match isIn e1 p e2 xH with
| Some (N0,e3) => mk_rsplit (PEc cI) (NPEpow e1 (Npos p)) e3
| Some (Npos q, e3) => mk_rsplit (NPEpow e1 (Npos q)) (NPEpow e1 (Npos (p - q))) e3
| None => mk_rsplit (NPEpow e1 (Npos p)) (PEc cI) e2
end in
NPEeval l (PEpow e1 (Npos p)) == NPEeval l (NPEmul (left res) (common res))
/\
NPEeval l e2 == NPEeval l (NPEmul (right res) (common res)).
Proof.
intros. unfold res;clear res; generalize (isIn_correct l e1 p e2 xH).
destruct (isIn e1 p e2 1). destruct p0.
Opaque NPEpow NPEmul.
destruct n;simpl;
(repeat rewrite NPEmul_correct;simpl;
repeat rewrite NPEpow_correct;simpl;
repeat rewrite pow_th.(rpow_pow_N);simpl).
intros (H, Hgt);split;try ring [H CRmorph.(morph1)].
intros (H, Hgt). simpl_pos_sub. simpl in H;split;try ring [H].
apply Z.gt_lt in Hgt.
now rewrite <- pow_pos_add, Pos.add_comm, Pos.sub_add.
simpl;intros. repeat rewrite NPEmul_correct;simpl.
rewrite NPEpow_correct;simpl. split;ring [CRmorph.(morph1)].
Qed.
Theorem split_aux_correct: forall l e1 p e2,
NPEeval l (PEpow e1 (Npos p)) ==
NPEeval l (NPEmul (left (split_aux e1 p e2)) (common (split_aux e1 p e2)))
/\
NPEeval l e2 == NPEeval l (NPEmul (right (split_aux e1 p e2))
(common (split_aux e1 p e2))).
Proof.
intros l; induction e1;intros k e2; try refine (split_aux_correct_1 l _ k e2);simpl.
generalize (IHe1_1 k e2); clear IHe1_1.
generalize (IHe1_2 k (rsplit_right (split_aux e1_1 k e2))); clear IHe1_2.
simpl. repeat (rewrite NPEmul_correct;simpl).
repeat rewrite pow_th.(rpow_pow_N);simpl.
intros (H1,H2) (H3,H4);split.
rewrite pow_pos_mul. rewrite H1;rewrite H3. ring.
rewrite H4;rewrite H2;ring.
destruct n;simpl.
split. repeat rewrite pow_th.(rpow_pow_N);simpl.
rewrite NPEmul_correct. simpl.
induction k;simpl;try ring [CRmorph.(morph1)]; ring [IHk CRmorph.(morph1)].
rewrite NPEmul_correct;simpl. ring [CRmorph.(morph1)].
generalize (IHe1 (p*k)%positive e2);clear IHe1;simpl.
repeat rewrite NPEmul_correct;simpl.
repeat rewrite pow_th.(rpow_pow_N);simpl.
rewrite pow_pos_pow_pos. intros [H1 H2];split;ring [H1 H2].
Qed.
Definition split e1 e2 := split_aux e1 xH e2.
Theorem split_correct_l: forall l e1 e2,
NPEeval l e1 == NPEeval l (NPEmul (left (split e1 e2))
(common (split e1 e2))).
Proof.
intros l e1 e2; case (split_aux_correct l e1 xH e2);simpl.
rewrite pow_th.(rpow_pow_N);simpl;auto.
Qed.
Theorem split_correct_r: forall l e1 e2,
NPEeval l e2 == NPEeval l (NPEmul (right (split e1 e2))
(common (split e1 e2))).
Proof.
intros l e1 e2; case (split_aux_correct l e1 xH e2);simpl;auto.
Qed.
Fixpoint Fnorm (e : FExpr) : linear :=
match e with
| FEc c => mk_linear (PEc c) (PEc cI) nil
| FEX x => mk_linear (PEX C x) (PEc cI) nil
| FEadd e1 e2 =>
let x := Fnorm e1 in
let y := Fnorm e2 in
let s := split (denum x) (denum y) in
mk_linear
(NPEadd (NPEmul (num x) (right s)) (NPEmul (num y) (left s)))
(NPEmul (left s) (NPEmul (right s) (common s)))
(condition x ++ condition y)
| FEsub e1 e2 =>
let x := Fnorm e1 in
let y := Fnorm e2 in
let s := split (denum x) (denum y) in
mk_linear
(NPEsub (NPEmul (num x) (right s)) (NPEmul (num y) (left s)))
(NPEmul (left s) (NPEmul (right s) (common s)))
(condition x ++ condition y)
| FEmul e1 e2 =>
let x := Fnorm e1 in
let y := Fnorm e2 in
let s1 := split (num x) (denum y) in
let s2 := split (num y) (denum x) in
mk_linear (NPEmul (left s1) (left s2))
(NPEmul (right s2) (right s1))
(condition x ++ condition y)
| FEopp e1 =>
let x := Fnorm e1 in
mk_linear (NPEopp (num x)) (denum x) (condition x)
| FEinv e1 =>
let x := Fnorm e1 in
mk_linear (denum x) (num x) (num x :: condition x)
| FEdiv e1 e2 =>
let x := Fnorm e1 in
let y := Fnorm e2 in
let s1 := split (num x) (num y) in
let s2 := split (denum x) (denum y) in
mk_linear (NPEmul (left s1) (right s2))
(NPEmul (left s2) (right s1))
(num y :: condition x ++ condition y)
| FEpow e1 n =>
let x := Fnorm e1 in
mk_linear (NPEpow (num x) n) (NPEpow (denum x) n) (condition x)
end.
(* Example *)
(*
Eval compute
in (Fnorm
(FEdiv
(FEc cI)
(FEadd (FEinv (FEX xH%positive)) (FEinv (FEX (xO xH)%positive))))).
*)
Lemma pow_pos_not_0 : forall x, ~x==0 -> forall p, ~pow_pos rmul x p == 0.
Proof.
induction p;simpl.
intro Hp;assert (H1 := @rmul_reg_l _ (pow_pos rmul x p * pow_pos rmul x p) 0 H).
apply IHp.
rewrite (@rmul_reg_l _ (pow_pos rmul x p) 0 IHp).
reflexivity.
rewrite H1. ring. rewrite Hp;ring.
intro Hp;apply IHp. rewrite (@rmul_reg_l _ (pow_pos rmul x p) 0 IHp).
reflexivity. rewrite Hp;ring. trivial.
Qed.
Theorem Pcond_Fnorm:
forall l e,
PCond l (condition (Fnorm e)) -> ~ NPEeval l (denum (Fnorm e)) == 0.
intros l e; elim e.
simpl; intros _ _; rewrite (morph1 CRmorph); exact rI_neq_rO.
simpl; intros _ _; rewrite (morph1 CRmorph); exact rI_neq_rO.
intros e1 Hrec1 e2 Hrec2 Hcond.
simpl condition in Hcond.
simpl denum.
rewrite NPEmul_correct.
simpl.
apply field_is_integral_domain.
intros HH; case Hrec1; auto.
apply PCond_app_inv_l with (1 := Hcond).
rewrite (split_correct_l l (denum (Fnorm e1)) (denum (Fnorm e2))).
rewrite NPEmul_correct; simpl; rewrite HH; ring.
intros HH; case Hrec2; auto.
apply PCond_app_inv_r with (1 := Hcond).
rewrite (split_correct_r l (denum (Fnorm e1)) (denum (Fnorm e2))); auto.
intros e1 Hrec1 e2 Hrec2 Hcond.
simpl condition in Hcond.
simpl denum.
rewrite NPEmul_correct.
simpl.
apply field_is_integral_domain.
intros HH; case Hrec1; auto.
apply PCond_app_inv_l with (1 := Hcond).
rewrite (split_correct_l l (denum (Fnorm e1)) (denum (Fnorm e2))).
rewrite NPEmul_correct; simpl; rewrite HH; ring.
intros HH; case Hrec2; auto.
apply PCond_app_inv_r with (1 := Hcond).
rewrite (split_correct_r l (denum (Fnorm e1)) (denum (Fnorm e2))); auto.
intros e1 Hrec1 e2 Hrec2 Hcond.
simpl condition in Hcond.
simpl denum.
rewrite NPEmul_correct.
simpl.
apply field_is_integral_domain.
intros HH; apply Hrec1.
apply PCond_app_inv_l with (1 := Hcond).
rewrite (split_correct_r l (num (Fnorm e2)) (denum (Fnorm e1))).
rewrite NPEmul_correct; simpl; rewrite HH; ring.
intros HH; apply Hrec2.
apply PCond_app_inv_r with (1 := Hcond).
rewrite (split_correct_r l (num (Fnorm e1)) (denum (Fnorm e2))).
rewrite NPEmul_correct; simpl; rewrite HH; ring.
intros e1 Hrec1 Hcond.
simpl condition in Hcond.
simpl denum.
auto.
intros e1 Hrec1 Hcond.
simpl condition in Hcond.
simpl denum.
apply PCond_cons_inv_l with (1:=Hcond).
intros e1 Hrec1 e2 Hrec2 Hcond.
simpl condition in Hcond.
simpl denum.
rewrite NPEmul_correct.
simpl.
apply field_is_integral_domain.
intros HH; apply Hrec1.
specialize PCond_cons_inv_r with (1:=Hcond); intro Hcond1.
apply PCond_app_inv_l with (1 := Hcond1).
rewrite (split_correct_l l (denum (Fnorm e1)) (denum (Fnorm e2))).
rewrite NPEmul_correct; simpl; rewrite HH; ring.
intros HH; apply PCond_cons_inv_l with (1:=Hcond).
rewrite (split_correct_r l (num (Fnorm e1)) (num (Fnorm e2))).
rewrite NPEmul_correct; simpl; rewrite HH; ring.
simpl;intros e1 Hrec1 n Hcond.
rewrite NPEpow_correct.
simpl;rewrite pow_th.(rpow_pow_N).
destruct n;simpl;intros.
apply AFth.(AF_1_neq_0). apply pow_pos_not_0;auto.
Qed.
Hint Resolve Pcond_Fnorm.
(***************************************************************************
Main theorem
***************************************************************************)
Theorem Fnorm_FEeval_PEeval:
forall l fe,
PCond l (condition (Fnorm fe)) ->
FEeval l fe == NPEeval l (num (Fnorm fe)) / NPEeval l (denum (Fnorm fe)).
Proof.
intros l fe; elim fe; simpl.
intros c H; rewrite CRmorph.(morph1); apply rdiv1.
intros p H; rewrite CRmorph.(morph1); apply rdiv1.
intros e1 He1 e2 He2 HH.
assert (HH1: PCond l (condition (Fnorm e1))).
apply PCond_app_inv_l with ( 1 := HH ).
assert (HH2: PCond l (condition (Fnorm e2))).
apply PCond_app_inv_r with ( 1 := HH ).
rewrite (He1 HH1); rewrite (He2 HH2).
rewrite NPEadd_correct; simpl.
repeat rewrite NPEmul_correct; simpl.
generalize (split_correct_l l (denum (Fnorm e1)) (denum (Fnorm e2)))
(split_correct_r l (denum (Fnorm e1)) (denum (Fnorm e2))).
repeat rewrite NPEmul_correct; simpl.
intros U1 U2; rewrite U1; rewrite U2.
apply rdiv2b; auto.
rewrite <- U1; auto.
rewrite <- U2; auto.
intros e1 He1 e2 He2 HH.
assert (HH1: PCond l (condition (Fnorm e1))).
apply PCond_app_inv_l with ( 1 := HH ).
assert (HH2: PCond l (condition (Fnorm e2))).
apply PCond_app_inv_r with ( 1 := HH ).
rewrite (He1 HH1); rewrite (He2 HH2).
rewrite NPEsub_correct; simpl.
repeat rewrite NPEmul_correct; simpl.
generalize (split_correct_l l (denum (Fnorm e1)) (denum (Fnorm e2)))
(split_correct_r l (denum (Fnorm e1)) (denum (Fnorm e2))).
repeat rewrite NPEmul_correct; simpl.
intros U1 U2; rewrite U1; rewrite U2.
apply rdiv3b; auto.
rewrite <- U1; auto.
rewrite <- U2; auto.
intros e1 He1 e2 He2 HH.
assert (HH1: PCond l (condition (Fnorm e1))).
apply PCond_app_inv_l with ( 1 := HH ).
assert (HH2: PCond l (condition (Fnorm e2))).
apply PCond_app_inv_r with ( 1 := HH ).
rewrite (He1 HH1); rewrite (He2 HH2).
repeat rewrite NPEmul_correct; simpl.
generalize (split_correct_l l (num (Fnorm e1)) (denum (Fnorm e2)))
(split_correct_r l (num (Fnorm e1)) (denum (Fnorm e2)))
(split_correct_l l (num (Fnorm e2)) (denum (Fnorm e1)))
(split_correct_r l (num (Fnorm e2)) (denum (Fnorm e1))).
repeat rewrite NPEmul_correct; simpl.
intros U1 U2 U3 U4; rewrite U1; rewrite U2; rewrite U3;
rewrite U4; simpl.
apply rdiv4b; auto.
rewrite <- U4; auto.
rewrite <- U2; auto.
intros e1 He1 HH.
rewrite NPEopp_correct; simpl; rewrite (He1 HH); apply rdiv5; auto.
intros e1 He1 HH.
assert (HH1: PCond l (condition (Fnorm e1))).
apply PCond_cons_inv_r with ( 1 := HH ).
rewrite (He1 HH1); apply rdiv6; auto.
apply PCond_cons_inv_l with ( 1 := HH ).
intros e1 He1 e2 He2 HH.
assert (HH1: PCond l (condition (Fnorm e1))).
apply PCond_app_inv_l with (condition (Fnorm e2)).
apply PCond_cons_inv_r with ( 1 := HH ).
assert (HH2: PCond l (condition (Fnorm e2))).
apply PCond_app_inv_r with (condition (Fnorm e1)).
apply PCond_cons_inv_r with ( 1 := HH ).
rewrite (He1 HH1); rewrite (He2 HH2).
repeat rewrite NPEmul_correct;simpl.
generalize (split_correct_l l (num (Fnorm e1)) (num (Fnorm e2)))
(split_correct_r l (num (Fnorm e1)) (num (Fnorm e2)))
(split_correct_l l (denum (Fnorm e1)) (denum (Fnorm e2)))
(split_correct_r l (denum (Fnorm e1)) (denum (Fnorm e2))).
repeat rewrite NPEmul_correct; simpl.
intros U1 U2 U3 U4; rewrite U1; rewrite U2; rewrite U3;
rewrite U4; simpl.
apply rdiv7b; auto.
rewrite <- U3; auto.
rewrite <- U2; auto.
apply PCond_cons_inv_l with ( 1 := HH ).
rewrite <- U4; auto.
intros e1 He1 n Hcond;assert (He1' := He1 Hcond);clear He1.
repeat rewrite NPEpow_correct;simpl;repeat rewrite pow_th.(rpow_pow_N).
rewrite He1';clear He1'.
destruct n;simpl. apply rdiv1.
generalize (NPEeval l (num (Fnorm e1))) (NPEeval l (denum (Fnorm e1)))
(Pcond_Fnorm _ _ Hcond).
intros r r0 Hdiff;induction p;simpl.
repeat (rewrite <- rdiv4;trivial).
rewrite IHp. reflexivity.
apply pow_pos_not_0;trivial.
apply pow_pos_not_0;trivial.
intro Hp. apply (pow_pos_not_0 Hdiff p).
rewrite (@rmul_reg_l (pow_pos rmul r0 p) (pow_pos rmul r0 p) 0).
reflexivity. apply pow_pos_not_0;trivial. ring [Hp].
rewrite <- rdiv4;trivial.
rewrite IHp;reflexivity.
apply pow_pos_not_0;trivial. apply pow_pos_not_0;trivial.
reflexivity.
Qed.
Theorem Fnorm_crossproduct:
forall l fe1 fe2,
let nfe1 := Fnorm fe1 in
let nfe2 := Fnorm fe2 in
NPEeval l (PEmul (num nfe1) (denum nfe2)) ==
NPEeval l (PEmul (num nfe2) (denum nfe1)) ->
PCond l (condition nfe1 ++ condition nfe2) ->
FEeval l fe1 == FEeval l fe2.
intros l fe1 fe2 nfe1 nfe2 Hcrossprod Hcond; subst nfe1 nfe2.
rewrite Fnorm_FEeval_PEeval by
apply PCond_app_inv_l with (1 := Hcond).
rewrite Fnorm_FEeval_PEeval by
apply PCond_app_inv_r with (1 := Hcond).
apply cross_product_eq; trivial.
apply Pcond_Fnorm.
apply PCond_app_inv_l with (1 := Hcond).
apply Pcond_Fnorm.
apply PCond_app_inv_r with (1 := Hcond).
Qed.
(* Correctness lemmas of reflexive tactics *)
Notation Ninterp_PElist := (interp_PElist rO radd rmul rsub ropp req phi Cp_phi rpow).
Notation Nmk_monpol_list := (mk_monpol_list cO cI cadd cmul csub copp ceqb cdiv).
Theorem Fnorm_correct:
forall n l lpe fe,
Ninterp_PElist l lpe ->
Peq ceqb (Nnorm n (Nmk_monpol_list lpe) (num (Fnorm fe))) (Pc cO) = true ->
PCond l (condition (Fnorm fe)) -> FEeval l fe == 0.
intros n l lpe fe Hlpe H H1;
apply eq_trans with (1 := Fnorm_FEeval_PEeval l fe H1).
apply rdiv8; auto.
transitivity (NPEeval l (PEc cO)); auto.
rewrite (norm_subst_ok Rsth Reqe ARth CRmorph pow_th cdiv_th n l lpe);auto.
change (NPEeval l (PEc cO)) with (Pphi 0 radd rmul phi l (Pc cO)).
apply (Peq_ok Rsth Reqe CRmorph);auto.
simpl. apply (morph0 CRmorph); auto.
Qed.
(* simplify a field expression into a fraction *)
(* TODO: simplify when den is constant... *)
Definition display_linear l num den :=
NPphi_dev l num / NPphi_dev l den.
Definition display_pow_linear l num den :=
NPphi_pow l num / NPphi_pow l den.
Theorem Field_rw_correct :
forall n lpe l,
Ninterp_PElist l lpe ->
forall lmp, Nmk_monpol_list lpe = lmp ->
forall fe nfe, Fnorm fe = nfe ->
PCond l (condition nfe) ->
FEeval l fe == display_linear l (Nnorm n lmp (num nfe)) (Nnorm n lmp (denum nfe)).
Proof.
intros n lpe l Hlpe lmp lmp_eq fe nfe eq_nfe H; subst nfe lmp.
apply eq_trans with (1 := Fnorm_FEeval_PEeval _ _ H).
unfold display_linear; apply SRdiv_ext;
eapply (ring_rw_correct Rsth Reqe ARth CRmorph);eauto.
Qed.
Theorem Field_rw_pow_correct :
forall n lpe l,
Ninterp_PElist l lpe ->
forall lmp, Nmk_monpol_list lpe = lmp ->
forall fe nfe, Fnorm fe = nfe ->
PCond l (condition nfe) ->
FEeval l fe == display_pow_linear l (Nnorm n lmp (num nfe)) (Nnorm n lmp (denum nfe)).
Proof.
intros n lpe l Hlpe lmp lmp_eq fe nfe eq_nfe H; subst nfe lmp.
apply eq_trans with (1 := Fnorm_FEeval_PEeval _ _ H).
unfold display_pow_linear; apply SRdiv_ext;
eapply (ring_rw_pow_correct Rsth Reqe ARth CRmorph);eauto.
Qed.
Theorem Field_correct :
forall n l lpe fe1 fe2, Ninterp_PElist l lpe ->
forall lmp, Nmk_monpol_list lpe = lmp ->
forall nfe1, Fnorm fe1 = nfe1 ->
forall nfe2, Fnorm fe2 = nfe2 ->
Peq ceqb (Nnorm n lmp (PEmul (num nfe1) (denum nfe2)))
(Nnorm n lmp (PEmul (num nfe2) (denum nfe1))) = true ->
PCond l (condition nfe1 ++ condition nfe2) ->
FEeval l fe1 == FEeval l fe2.
Proof.
intros n l lpe fe1 fe2 Hlpe lmp eq_lmp nfe1 eq1 nfe2 eq2 Hnorm Hcond; subst nfe1 nfe2 lmp.
apply Fnorm_crossproduct; trivial.
eapply (ring_correct Rsth Reqe ARth CRmorph); eauto.
Qed.
(* simplify a field equation : generate the crossproduct and simplify
polynomials *)
Theorem Field_simplify_eq_old_correct :
forall l fe1 fe2 nfe1 nfe2,
Fnorm fe1 = nfe1 ->
Fnorm fe2 = nfe2 ->
NPphi_dev l (Nnorm O nil (PEmul (num nfe1) (denum nfe2))) ==
NPphi_dev l (Nnorm O nil (PEmul (num nfe2) (denum nfe1))) ->
PCond l (condition nfe1 ++ condition nfe2) ->
FEeval l fe1 == FEeval l fe2.
Proof.
intros l fe1 fe2 nfe1 nfe2 eq1 eq2 Hcrossprod Hcond; subst nfe1 nfe2.
apply Fnorm_crossproduct; trivial.
match goal with
[ |- NPEeval l ?x == NPEeval l ?y] =>
rewrite (ring_rw_correct Rsth Reqe ARth CRmorph pow_th cdiv_th get_sign_spec
O nil l I Logic.eq_refl x Logic.eq_refl);
rewrite (ring_rw_correct Rsth Reqe ARth CRmorph pow_th cdiv_th get_sign_spec
O nil l I Logic.eq_refl y Logic.eq_refl)
end.
trivial.
Qed.
Theorem Field_simplify_eq_correct :
forall n l lpe fe1 fe2,
Ninterp_PElist l lpe ->
forall lmp, Nmk_monpol_list lpe = lmp ->
forall nfe1, Fnorm fe1 = nfe1 ->
forall nfe2, Fnorm fe2 = nfe2 ->
forall den, split (denum nfe1) (denum nfe2) = den ->
NPphi_dev l (Nnorm n lmp (PEmul (num nfe1) (right den))) ==
NPphi_dev l (Nnorm n lmp (PEmul (num nfe2) (left den))) ->
PCond l (condition nfe1 ++ condition nfe2) ->
FEeval l fe1 == FEeval l fe2.
Proof.
intros n l lpe fe1 fe2 Hlpe lmp Hlmp nfe1 eq1 nfe2 eq2 den eq3 Hcrossprod Hcond;
subst nfe1 nfe2 den lmp.
apply Fnorm_crossproduct; trivial.
simpl.
rewrite (split_correct_l l (denum (Fnorm fe1)) (denum (Fnorm fe2))).
rewrite (split_correct_r l (denum (Fnorm fe1)) (denum (Fnorm fe2))).
rewrite NPEmul_correct.
rewrite NPEmul_correct.
simpl.
repeat rewrite (ARmul_assoc ARth).
rewrite <-(
let x := PEmul (num (Fnorm fe1))
(rsplit_right (split (denum (Fnorm fe1)) (denum (Fnorm fe2)))) in
ring_rw_correct Rsth Reqe ARth CRmorph pow_th cdiv_th get_sign_spec n lpe l
Hlpe Logic.eq_refl
x Logic.eq_refl) in Hcrossprod.
rewrite <-(
let x := (PEmul (num (Fnorm fe2))
(rsplit_left
(split (denum (Fnorm fe1)) (denum (Fnorm fe2))))) in
ring_rw_correct Rsth Reqe ARth CRmorph pow_th cdiv_th get_sign_spec n lpe l
Hlpe Logic.eq_refl
x Logic.eq_refl) in Hcrossprod.
simpl in Hcrossprod.
rewrite Hcrossprod.
reflexivity.
Qed.
Theorem Field_simplify_eq_pow_correct :
forall n l lpe fe1 fe2,
Ninterp_PElist l lpe ->
forall lmp, Nmk_monpol_list lpe = lmp ->
forall nfe1, Fnorm fe1 = nfe1 ->
forall nfe2, Fnorm fe2 = nfe2 ->
forall den, split (denum nfe1) (denum nfe2) = den ->
NPphi_pow l (Nnorm n lmp (PEmul (num nfe1) (right den))) ==
NPphi_pow l (Nnorm n lmp (PEmul (num nfe2) (left den))) ->
PCond l (condition nfe1 ++ condition nfe2) ->
FEeval l fe1 == FEeval l fe2.
Proof.
intros n l lpe fe1 fe2 Hlpe lmp Hlmp nfe1 eq1 nfe2 eq2 den eq3 Hcrossprod Hcond;
subst nfe1 nfe2 den lmp.
apply Fnorm_crossproduct; trivial.
simpl.
rewrite (split_correct_l l (denum (Fnorm fe1)) (denum (Fnorm fe2))).
rewrite (split_correct_r l (denum (Fnorm fe1)) (denum (Fnorm fe2))).
rewrite NPEmul_correct.
rewrite NPEmul_correct.
simpl.
repeat rewrite (ARmul_assoc ARth).
rewrite <-(
let x := PEmul (num (Fnorm fe1))
(rsplit_right (split (denum (Fnorm fe1)) (denum (Fnorm fe2)))) in
ring_rw_pow_correct Rsth Reqe ARth CRmorph pow_th cdiv_th get_sign_spec n lpe l
Hlpe Logic.eq_refl
x Logic.eq_refl) in Hcrossprod.
rewrite <-(
let x := (PEmul (num (Fnorm fe2))
(rsplit_left
(split (denum (Fnorm fe1)) (denum (Fnorm fe2))))) in
ring_rw_pow_correct Rsth Reqe ARth CRmorph pow_th cdiv_th get_sign_spec n lpe l
Hlpe Logic.eq_refl
x Logic.eq_refl) in Hcrossprod.
simpl in Hcrossprod.
rewrite Hcrossprod.
reflexivity.
Qed.
Theorem Field_simplify_eq_pow_in_correct :
forall n l lpe fe1 fe2,
Ninterp_PElist l lpe ->
forall lmp, Nmk_monpol_list lpe = lmp ->
forall nfe1, Fnorm fe1 = nfe1 ->
forall nfe2, Fnorm fe2 = nfe2 ->
forall den, split (denum nfe1) (denum nfe2) = den ->
forall np1, Nnorm n lmp (PEmul (num nfe1) (right den)) = np1 ->
forall np2, Nnorm n lmp (PEmul (num nfe2) (left den)) = np2 ->
FEeval l fe1 == FEeval l fe2 ->
PCond l (condition nfe1 ++ condition nfe2) ->
NPphi_pow l np1 ==
NPphi_pow l np2.
Proof.
intros. subst nfe1 nfe2 lmp np1 np2.
repeat rewrite (Pphi_pow_ok Rsth Reqe ARth CRmorph pow_th get_sign_spec).
repeat (rewrite <- (norm_subst_ok Rsth Reqe ARth CRmorph pow_th);trivial). simpl.
assert (N1 := Pcond_Fnorm _ _ (PCond_app_inv_l _ _ _ H7)).
assert (N2 := Pcond_Fnorm _ _ (PCond_app_inv_r _ _ _ H7)).
apply (@rmul_reg_l (NPEeval l (rsplit_common den))).
intro Heq;apply N1.
rewrite (split_correct_l l (denum (Fnorm fe1)) (denum (Fnorm fe2))).
rewrite H3. rewrite NPEmul_correct. simpl. ring [Heq].
repeat rewrite (ARth.(ARmul_comm) (NPEeval l (rsplit_common den))).
repeat rewrite <- ARth.(ARmul_assoc).
change (NPEeval l (rsplit_right den) * NPEeval l (rsplit_common den)) with
(NPEeval l (PEmul (rsplit_right den) (rsplit_common den))).
change (NPEeval l (rsplit_left den) * NPEeval l (rsplit_common den)) with
(NPEeval l (PEmul (rsplit_left den) (rsplit_common den))).
repeat rewrite <- NPEmul_correct. rewrite <- H3. rewrite <- split_correct_l.
rewrite <- split_correct_r.
apply (@rmul_reg_l (/NPEeval l (denum (Fnorm fe2)))).
intro Heq; apply AFth.(AF_1_neq_0).
rewrite <- (@AFinv_l AFth (NPEeval l (denum (Fnorm fe2))));trivial.
ring [Heq]. rewrite (ARth.(ARmul_comm) (/ NPEeval l (denum (Fnorm fe2)))).
repeat rewrite <- (ARth.(ARmul_assoc)).
rewrite <- (AFth.(AFdiv_def)). rewrite rdiv_r_r by trivial.
apply (@rmul_reg_l (/NPEeval l (denum (Fnorm fe1)))).
intro Heq; apply AFth.(AF_1_neq_0).
rewrite <- (@AFinv_l AFth (NPEeval l (denum (Fnorm fe1))));trivial.
ring [Heq]. repeat rewrite (ARth.(ARmul_comm) (/ NPEeval l (denum (Fnorm fe1)))).
repeat rewrite <- (ARth.(ARmul_assoc)).
repeat rewrite <- (AFth.(AFdiv_def)). rewrite rdiv_r_r by trivial.
rewrite (AFth.(AFdiv_def)). ring_simplify. unfold SRopp.
rewrite (ARth.(ARmul_comm) (/ NPEeval l (denum (Fnorm fe2)))).
repeat rewrite <- (AFth.(AFdiv_def)).
repeat rewrite <- Fnorm_FEeval_PEeval ; trivial.
apply (PCond_app_inv_r _ _ _ H7). apply (PCond_app_inv_l _ _ _ H7).
Qed.
Theorem Field_simplify_eq_in_correct :
forall n l lpe fe1 fe2,
Ninterp_PElist l lpe ->
forall lmp, Nmk_monpol_list lpe = lmp ->
forall nfe1, Fnorm fe1 = nfe1 ->
forall nfe2, Fnorm fe2 = nfe2 ->
forall den, split (denum nfe1) (denum nfe2) = den ->
forall np1, Nnorm n lmp (PEmul (num nfe1) (right den)) = np1 ->
forall np2, Nnorm n lmp (PEmul (num nfe2) (left den)) = np2 ->
FEeval l fe1 == FEeval l fe2 ->
PCond l (condition nfe1 ++ condition nfe2) ->
NPphi_dev l np1 ==
NPphi_dev l np2.
Proof.
intros. subst nfe1 nfe2 lmp np1 np2.
repeat rewrite (Pphi_dev_ok Rsth Reqe ARth CRmorph get_sign_spec).
repeat (rewrite <- (norm_subst_ok Rsth Reqe ARth CRmorph pow_th);trivial). simpl.
assert (N1 := Pcond_Fnorm _ _ (PCond_app_inv_l _ _ _ H7)).
assert (N2 := Pcond_Fnorm _ _ (PCond_app_inv_r _ _ _ H7)).
apply (@rmul_reg_l (NPEeval l (rsplit_common den))).
intro Heq;apply N1.
rewrite (split_correct_l l (denum (Fnorm fe1)) (denum (Fnorm fe2))).
rewrite H3. rewrite NPEmul_correct. simpl. ring [Heq].
repeat rewrite (ARth.(ARmul_comm) (NPEeval l (rsplit_common den))).
repeat rewrite <- ARth.(ARmul_assoc).
change (NPEeval l (rsplit_right den) * NPEeval l (rsplit_common den)) with
(NPEeval l (PEmul (rsplit_right den) (rsplit_common den))).
change (NPEeval l (rsplit_left den) * NPEeval l (rsplit_common den)) with
(NPEeval l (PEmul (rsplit_left den) (rsplit_common den))).
repeat rewrite <- NPEmul_correct;rewrite <- H3. rewrite <- split_correct_l.
rewrite <- split_correct_r.
apply (@rmul_reg_l (/NPEeval l (denum (Fnorm fe2)))).
intro Heq; apply AFth.(AF_1_neq_0).
rewrite <- (@AFinv_l AFth (NPEeval l (denum (Fnorm fe2))));trivial.
ring [Heq]. rewrite (ARth.(ARmul_comm) (/ NPEeval l (denum (Fnorm fe2)))).
repeat rewrite <- (ARth.(ARmul_assoc)).
rewrite <- (AFth.(AFdiv_def)). rewrite rdiv_r_r by trivial.
apply (@rmul_reg_l (/NPEeval l (denum (Fnorm fe1)))).
intro Heq; apply AFth.(AF_1_neq_0).
rewrite <- (@AFinv_l AFth (NPEeval l (denum (Fnorm fe1))));trivial.
ring [Heq]. repeat rewrite (ARth.(ARmul_comm) (/ NPEeval l (denum (Fnorm fe1)))).
repeat rewrite <- (ARth.(ARmul_assoc)).
repeat rewrite <- (AFth.(AFdiv_def)). rewrite rdiv_r_r by trivial.
rewrite (AFth.(AFdiv_def)). ring_simplify. unfold SRopp.
rewrite (ARth.(ARmul_comm) (/ NPEeval l (denum (Fnorm fe2)))).
repeat rewrite <- (AFth.(AFdiv_def)).
repeat rewrite <- Fnorm_FEeval_PEeval;trivial.
apply (PCond_app_inv_r _ _ _ H7). apply (PCond_app_inv_l _ _ _ H7).
Qed.
Section Fcons_impl.
Variable Fcons : PExpr C -> list (PExpr C) -> list (PExpr C).
Hypothesis PCond_fcons_inv : forall l a l1,
PCond l (Fcons a l1) -> ~ NPEeval l a == 0 /\ PCond l l1.
Fixpoint Fapp (l m:list (PExpr C)) {struct l} : list (PExpr C) :=
match l with
| nil => m
| cons a l1 => Fcons a (Fapp l1 m)
end.
Lemma fcons_correct : forall l l1,
(forall lock, lock = PCond l -> lock (Fapp l1 nil)) -> PCond l l1.
Proof.
intros l l1 h1; assert (H := h1 (PCond l) (refl_equal _));clear h1.
induction l1; simpl; intros.
trivial.
elim PCond_fcons_inv with (1 := H); intros.
destruct l1; trivial. split; trivial. apply IHl1; trivial.
Qed.
End Fcons_impl.
Section Fcons_simpl.
(* Some general simpifications of the condition: eliminate duplicates,
split multiplications *)
Fixpoint Fcons (e:PExpr C) (l:list (PExpr C)) {struct l} : list (PExpr C) :=
match l with
nil => cons e nil
| cons a l1 => if PExpr_eq e a then l else cons a (Fcons e l1)
end.
Theorem PFcons_fcons_inv:
forall l a l1, PCond l (Fcons a l1) -> ~ NPEeval l a == 0 /\ PCond l l1.
intros l a l1; elim l1; simpl Fcons; auto.
simpl; auto.
intros a0 l0.
generalize (PExpr_eq_semi_correct l a a0); case (PExpr_eq a a0).
intros H H0 H1; split; auto.
rewrite H; auto.
generalize (PCond_cons_inv_l _ _ _ H1); simpl; auto.
intros H H0 H1;
assert (Hp: ~ NPEeval l a0 == 0 /\ (~ NPEeval l a == 0 /\ PCond l l0)).
split.
generalize (PCond_cons_inv_l _ _ _ H1); simpl; auto.
apply H0.
generalize (PCond_cons_inv_r _ _ _ H1); simpl; auto.
generalize Hp; case l0; simpl; intuition.
Qed.
(* equality of normal forms rather than syntactic equality *)
Fixpoint Fcons0 (e:PExpr C) (l:list (PExpr C)) {struct l} : list (PExpr C) :=
match l with
nil => cons e nil
| cons a l1 =>
if Peq ceqb (Nnorm O nil e) (Nnorm O nil a) then l
else cons a (Fcons0 e l1)
end.
Theorem PFcons0_fcons_inv:
forall l a l1, PCond l (Fcons0 a l1) -> ~ NPEeval l a == 0 /\ PCond l l1.
intros l a l1; elim l1; simpl Fcons0; auto.
simpl; auto.
intros a0 l0.
generalize (ring_correct Rsth Reqe ARth CRmorph pow_th cdiv_th O l nil a a0). simpl.
case (Peq ceqb (Nnorm O nil a) (Nnorm O nil a0)).
intros H H0 H1; split; auto.
rewrite H; auto.
generalize (PCond_cons_inv_l _ _ _ H1); simpl; auto.
intros H H0 H1;
assert (Hp: ~ NPEeval l a0 == 0 /\ (~ NPEeval l a == 0 /\ PCond l l0)).
split.
generalize (PCond_cons_inv_l _ _ _ H1); simpl; auto.
apply H0.
generalize (PCond_cons_inv_r _ _ _ H1); simpl; auto.
clear get_sign get_sign_spec.
generalize Hp; case l0; simpl; intuition.
Qed.
(* split factorized denominators *)
Fixpoint Fcons00 (e:PExpr C) (l:list (PExpr C)) {struct e} : list (PExpr C) :=
match e with
PEmul e1 e2 => Fcons00 e1 (Fcons00 e2 l)
| PEpow e1 _ => Fcons00 e1 l
| _ => Fcons0 e l
end.
Theorem PFcons00_fcons_inv:
forall l a l1, PCond l (Fcons00 a l1) -> ~ NPEeval l a == 0 /\ PCond l l1.
intros l a; elim a; try (intros; apply PFcons0_fcons_inv; auto; fail).
intros p H p0 H0 l1 H1.
simpl in H1.
case (H _ H1); intros H2 H3.
case (H0 _ H3); intros H4 H5; split; auto.
simpl.
apply field_is_integral_domain; trivial.
simpl;intros. rewrite pow_th.(rpow_pow_N).
destruct (H _ H0);split;auto.
destruct n;simpl. apply AFth.(AF_1_neq_0).
apply pow_pos_not_0;trivial.
Qed.
Definition Pcond_simpl_gen :=
fcons_correct _ PFcons00_fcons_inv.
(* Specific case when the equality test of coefs is complete w.r.t. the
field equality: non-zero coefs can be eliminated, and opposite can
be simplified (if -1 <> 0) *)
Hypothesis ceqb_complete : forall c1 c2, phi c1 == phi c2 -> ceqb c1 c2 = true.
Lemma ceqb_rect_complete : forall c1 c2 (A:Type) (x y:A) (P:A->Type),
(phi c1 == phi c2 -> P x) ->
(~ phi c1 == phi c2 -> P y) ->
P (if ceqb c1 c2 then x else y).
Proof.
intros.
generalize (fun h => X (morph_eq CRmorph c1 c2 h)).
generalize (@ceqb_complete c1 c2).
case (c1 ?=! c2); auto; intros.
apply X0.
red; intro.
absurd (false = true); auto; discriminate.
Qed.
Fixpoint Fcons1 (e:PExpr C) (l:list (PExpr C)) {struct e} : list (PExpr C) :=
match e with
PEmul e1 e2 => Fcons1 e1 (Fcons1 e2 l)
| PEpow e _ => Fcons1 e l
| PEopp e => if ceqb (copp cI) cO then absurd_PCond else Fcons1 e l
| PEc c => if ceqb c cO then absurd_PCond else l
| _ => Fcons0 e l
end.
Theorem PFcons1_fcons_inv:
forall l a l1, PCond l (Fcons1 a l1) -> ~ NPEeval l a == 0 /\ PCond l l1.
intros l a; elim a; try (intros; apply PFcons0_fcons_inv; auto; fail).
simpl; intros c l1.
apply ceqb_rect_complete; intros.
elim (@absurd_PCond_bottom l H0).
split; trivial.
rewrite <- (morph0 CRmorph); trivial.
intros p H p0 H0 l1 H1.
simpl in H1.
case (H _ H1); intros H2 H3.
case (H0 _ H3); intros H4 H5; split; auto.
simpl.
apply field_is_integral_domain; trivial.
simpl; intros p H l1.
apply ceqb_rect_complete; intros.
elim (@absurd_PCond_bottom l H1).
destruct (H _ H1).
split; trivial.
apply ropp_neq_0; trivial.
rewrite (morph_opp CRmorph) in H0.
rewrite (morph1 CRmorph) in H0.
rewrite (morph0 CRmorph) in H0.
trivial.
intros;simpl. destruct (H _ H0);split;trivial.
rewrite pow_th.(rpow_pow_N). destruct n;simpl.
apply AFth.(AF_1_neq_0). apply pow_pos_not_0;trivial.
Qed.
Definition Fcons2 e l := Fcons1 (PExpr_simp e) l.
Theorem PFcons2_fcons_inv:
forall l a l1, PCond l (Fcons2 a l1) -> ~ NPEeval l a == 0 /\ PCond l l1.
unfold Fcons2; intros l a l1 H; split;
case (PFcons1_fcons_inv l (PExpr_simp a) l1); auto.
intros H1 H2 H3; case H1.
transitivity (NPEeval l a); trivial.
apply PExpr_simp_correct.
Qed.
Definition Pcond_simpl_complete :=
fcons_correct _ PFcons2_fcons_inv.
End Fcons_simpl.
End AlmostField.
Section FieldAndSemiField.
Record field_theory : Prop := mk_field {
F_R : ring_theory rO rI radd rmul rsub ropp req;
F_1_neq_0 : ~ 1 == 0;
Fdiv_def : forall p q, p / q == p * / q;
Finv_l : forall p, ~ p == 0 -> / p * p == 1
}.
Definition F2AF f :=
mk_afield
(Rth_ARth Rsth Reqe f.(F_R)) f.(F_1_neq_0) f.(Fdiv_def) f.(Finv_l).
Record semi_field_theory : Prop := mk_sfield {
SF_SR : semi_ring_theory rO rI radd rmul req;
SF_1_neq_0 : ~ 1 == 0;
SFdiv_def : forall p q, p / q == p * / q;
SFinv_l : forall p, ~ p == 0 -> / p * p == 1
}.
End FieldAndSemiField.
End MakeFieldPol.
Definition SF2AF R (rO rI:R) radd rmul rdiv rinv req Rsth
(sf:semi_field_theory rO rI radd rmul rdiv rinv req) :=
mk_afield _ _
(SRth_ARth Rsth sf.(SF_SR))
sf.(SF_1_neq_0)
sf.(SFdiv_def)
sf.(SFinv_l).
Section Complete.
Variable R : Type.
Variable (rO rI : R) (radd rmul rsub: R->R->R) (ropp : R -> R).
Variable (rdiv : R -> R -> R) (rinv : R -> R).
Variable req : R -> R -> Prop.
Notation "0" := rO. Notation "1" := rI.
Notation "x + y" := (radd x y). Notation "x * y " := (rmul x y).
Notation "x - y " := (rsub x y). Notation "- x" := (ropp x).
Notation "x / y " := (rdiv x y). Notation "/ x" := (rinv x).
Notation "x == y" := (req x y) (at level 70, no associativity).
Variable Rsth : Setoid_Theory R req.
Add Setoid R req Rsth as R_setoid3.
Variable Reqe : ring_eq_ext radd rmul ropp req.
Add Morphism radd : radd_ext3. exact (Radd_ext Reqe). Qed.
Add Morphism rmul : rmul_ext3. exact (Rmul_ext Reqe). Qed.
Add Morphism ropp : ropp_ext3. exact (Ropp_ext Reqe). Qed.
Section AlmostField.
Variable AFth : almost_field_theory rO rI radd rmul rsub ropp rdiv rinv req.
Let ARth := AFth.(AF_AR).
Let rI_neq_rO := AFth.(AF_1_neq_0).
Let rdiv_def := AFth.(AFdiv_def).
Let rinv_l := AFth.(AFinv_l).
Hypothesis S_inj : forall x y, 1+x==1+y -> x==y.
Hypothesis gen_phiPOS_not_0 : forall p, ~ gen_phiPOS1 rI radd rmul p == 0.
Lemma add_inj_r : forall p x y,
gen_phiPOS1 rI radd rmul p + x == gen_phiPOS1 rI radd rmul p + y -> x==y.
intros p x y.
elim p using Pos.peano_ind; simpl; intros.
apply S_inj; trivial.
apply H.
apply S_inj.
repeat rewrite (ARadd_assoc ARth).
rewrite <- (ARgen_phiPOS_Psucc Rsth Reqe ARth); trivial.
Qed.
Lemma gen_phiPOS_inj : forall x y,
gen_phiPOS rI radd rmul x == gen_phiPOS rI radd rmul y ->
x = y.
intros x y.
repeat rewrite <- (same_gen Rsth Reqe ARth).
case (Pos.compare_spec x y).
intros.
trivial.
intros.
elim gen_phiPOS_not_0 with (y - x)%positive.
apply add_inj_r with x.
symmetry.
rewrite (ARadd_0_r Rsth ARth).
rewrite <- (ARgen_phiPOS_add Rsth Reqe ARth).
now rewrite Pos.add_comm, Pos.sub_add.
intros.
elim gen_phiPOS_not_0 with (x - y)%positive.
apply add_inj_r with y.
rewrite (ARadd_0_r Rsth ARth).
rewrite <- (ARgen_phiPOS_add Rsth Reqe ARth).
now rewrite Pos.add_comm, Pos.sub_add.
Qed.
Lemma gen_phiN_inj : forall x y,
gen_phiN rO rI radd rmul x == gen_phiN rO rI radd rmul y ->
x = y.
destruct x; destruct y; simpl; intros; trivial.
elim gen_phiPOS_not_0 with p.
symmetry .
rewrite (same_gen Rsth Reqe ARth); trivial.
elim gen_phiPOS_not_0 with p.
rewrite (same_gen Rsth Reqe ARth); trivial.
rewrite gen_phiPOS_inj with (1 := H); trivial.
Qed.
Lemma gen_phiN_complete : forall x y,
gen_phiN rO rI radd rmul x == gen_phiN rO rI radd rmul y ->
N.eqb x y = true.
Proof.
intros. now apply N.eqb_eq, gen_phiN_inj.
Qed.
End AlmostField.
Section Field.
Variable Fth : field_theory rO rI radd rmul rsub ropp rdiv rinv req.
Let Rth := Fth.(F_R).
Let rI_neq_rO := Fth.(F_1_neq_0).
Let rdiv_def := Fth.(Fdiv_def).
Let rinv_l := Fth.(Finv_l).
Let AFth := F2AF Rsth Reqe Fth.
Let ARth := Rth_ARth Rsth Reqe Rth.
Lemma ring_S_inj : forall x y, 1+x==1+y -> x==y.
intros.
transitivity (x + (1 + - (1))).
rewrite (Ropp_def Rth).
symmetry .
apply (ARadd_0_r Rsth ARth).
transitivity (y + (1 + - (1))).
repeat rewrite <- (ARplus_assoc ARth).
repeat rewrite (ARadd_assoc ARth).
apply (Radd_ext Reqe).
repeat rewrite <- (ARadd_comm ARth 1).
trivial.
reflexivity.
rewrite (Ropp_def Rth).
apply (ARadd_0_r Rsth ARth).
Qed.
Hypothesis gen_phiPOS_not_0 : forall p, ~ gen_phiPOS1 rI radd rmul p == 0.
Let gen_phiPOS_inject :=
gen_phiPOS_inj AFth ring_S_inj gen_phiPOS_not_0.
Lemma gen_phiPOS_discr_sgn : forall x y,
~ gen_phiPOS rI radd rmul x == - gen_phiPOS rI radd rmul y.
red; intros.
apply gen_phiPOS_not_0 with (y + x)%positive.
rewrite (ARgen_phiPOS_add Rsth Reqe ARth).
transitivity (gen_phiPOS1 1 radd rmul y + - gen_phiPOS1 1 radd rmul y).
apply (Radd_ext Reqe); trivial.
reflexivity.
rewrite (same_gen Rsth Reqe ARth).
rewrite (same_gen Rsth Reqe ARth).
trivial.
apply (Ropp_def Rth).
Qed.
Lemma gen_phiZ_inj : forall x y,
gen_phiZ rO rI radd rmul ropp x == gen_phiZ rO rI radd rmul ropp y ->
x = y.
destruct x; destruct y; simpl; intros.
trivial.
elim gen_phiPOS_not_0 with p.
rewrite (same_gen Rsth Reqe ARth).
symmetry ; trivial.
elim gen_phiPOS_not_0 with p.
rewrite (same_gen Rsth Reqe ARth).
rewrite <- (Ropp_opp Rsth Reqe Rth (gen_phiPOS 1 radd rmul p)).
rewrite <- H.
apply (ARopp_zero Rsth Reqe ARth).
elim gen_phiPOS_not_0 with p.
rewrite (same_gen Rsth Reqe ARth).
trivial.
rewrite gen_phiPOS_inject with (1 := H); trivial.
elim gen_phiPOS_discr_sgn with (1 := H).
elim gen_phiPOS_not_0 with p.
rewrite (same_gen Rsth Reqe ARth).
rewrite <- (Ropp_opp Rsth Reqe Rth (gen_phiPOS 1 radd rmul p)).
rewrite H.
apply (ARopp_zero Rsth Reqe ARth).
elim gen_phiPOS_discr_sgn with p0 p.
symmetry ; trivial.
replace p0 with p; trivial.
apply gen_phiPOS_inject.
rewrite <- (Ropp_opp Rsth Reqe Rth (gen_phiPOS 1 radd rmul p)).
rewrite <- (Ropp_opp Rsth Reqe Rth (gen_phiPOS 1 radd rmul p0)).
rewrite H; trivial.
reflexivity.
Qed.
Lemma gen_phiZ_complete : forall x y,
gen_phiZ rO rI radd rmul ropp x == gen_phiZ rO rI radd rmul ropp y ->
Zeq_bool x y = true.
intros.
replace y with x.
unfold Zeq_bool.
rewrite Z.compare_refl; trivial.
apply gen_phiZ_inj; trivial.
Qed.
End Field.
End Complete.
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