(************************************************************************) (* * The Coq Proof Assistant / The Coq Development Team *) (* v * INRIA, CNRS and contributors - Copyright 1999-2018 *) (* R->R) (ropp : R->R). Variable req : R -> R -> Prop. (* Ring properties *) Variable Rsth : Equivalence req. Variable Reqe : ring_eq_ext radd rmul ropp req. Variable ARth : almost_ring_theory rO rI radd rmul rsub ropp req. (* 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. (* 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. (* division is ok *) Variable cdiv: C -> C -> C * C. Variable div_th: div_theory req cadd cmul phi cdiv. (* R notations *) Notation "0" := rO. Notation "1" := rI. Infix "+" := radd. Infix "*" := rmul. Infix "-" := rsub. Notation "- x" := (ropp x). Infix "==" := req. Infix "^" := (pow_pos rmul). (* C notations *) Infix "+!" := cadd. Infix "*!" := cmul. Infix "-! " := csub. Notation "-! x" := (copp x). Infix "?=!" := ceqb. Notation "[ x ]" := (phi x). (* Useful tactics *) Add Morphism radd with signature (req ==> req ==> req) as radd_ext. Proof. exact (Radd_ext Reqe). Qed. Add Morphism rmul with signature (req ==> req ==> req) as rmul_ext. Proof. exact (Rmul_ext Reqe). Qed. Add Morphism ropp with signature (req ==> req) as ropp_ext. Proof. exact (Ropp_ext Reqe). Qed. Add Morphism rsub with signature (req ==> req ==> req) as rsub_ext. Proof. exact (ARsub_ext Rsth Reqe ARth). Qed. Ltac rsimpl := gen_srewrite Rsth Reqe ARth. Ltac add_push := gen_add_push radd Rsth Reqe ARth. Ltac mul_push := gen_mul_push rmul Rsth Reqe ARth. Ltac add_permut_rec t := match t with | ?x + ?y => add_permut_rec y || add_permut_rec x | _ => add_push t; apply (Radd_ext Reqe); [|reflexivity] end. Ltac add_permut := repeat (reflexivity || match goal with |- ?t == _ => add_permut_rec t end). Ltac mul_permut_rec t := match t with | ?x * ?y => mul_permut_rec y || mul_permut_rec x | _ => mul_push t; apply (Rmul_ext Reqe); [|reflexivity] end. Ltac mul_permut := repeat (reflexivity || match goal with |- ?t == _ => mul_permut_rec t end). (* Definition of multivariable polynomials with coefficients in C : Type [Pol] represents [X1 ... Xn]. The representation is Horner's where a [n] variable polynomial (C[X1..Xn]) is seen as a polynomial on [X1] which coefficients are polynomials with [n-1] variables (C[X2..Xn]). There are several optimisations to make the repr compacter: - [Pc c] is the constant polynomial of value c == c*X1^0*..*Xn^0 - [Pinj j Q] is a polynomial constant w.r.t the [j] first variables. variable indices are shifted of j in Q. == X1^0 *..* Xj^0 * Q{X1 <- Xj+1;..; Xn-j <- Xn} - [PX P i Q] is an optimised Horner form of P*X^i + Q with P not the null polynomial == P * X1^i + Q{X1 <- X2; ..; Xn-1 <- Xn} In addition: - polynomials of the form (PX (PX P i (Pc 0)) j Q) are forbidden since they can be represented by the simpler form (PX P (i+j) Q) - (Pinj i (Pinj j P)) is (Pinj (i+j) P) - (Pinj i (Pc c)) is (Pc c) *) Inductive Pol : Type := | Pc : C -> Pol | Pinj : positive -> Pol -> Pol | PX : Pol -> positive -> Pol -> Pol. Definition P0 := Pc cO. Definition P1 := Pc cI. Fixpoint Peq (P P' : Pol) {struct P'} : bool := match P, P' with | Pc c, Pc c' => c ?=! c' | Pinj j Q, Pinj j' Q' => match j ?= j' with | Eq => Peq Q Q' | _ => false end | PX P i Q, PX P' i' Q' => match i ?= i' with | Eq => if Peq P P' then Peq Q Q' else false | _ => false end | _, _ => false end. Infix "?==" := Peq. Definition mkPinj j P := match P with | Pc _ => P | Pinj j' Q => Pinj (j + j') Q | _ => Pinj j P end. Definition mkPinj_pred j P:= match j with | xH => P | xO j => Pinj (Pos.pred_double j) P | xI j => Pinj (xO j) P end. Definition mkPX P i Q := match P with | Pc c => if c ?=! cO then mkPinj xH Q else PX P i Q | Pinj _ _ => PX P i Q | PX P' i' Q' => if Q' ?== P0 then PX P' (i' + i) Q else PX P i Q end. Definition mkXi i := PX P1 i P0. Definition mkX := mkXi 1. (** Opposite of addition *) Fixpoint Popp (P:Pol) : Pol := match P with | Pc c => Pc (-! c) | Pinj j Q => Pinj j (Popp Q) | PX P i Q => PX (Popp P) i (Popp Q) end. Notation "-- P" := (Popp P). (** Addition et subtraction *) Fixpoint PaddC (P:Pol) (c:C) : Pol := match P with | Pc c1 => Pc (c1 +! c) | Pinj j Q => Pinj j (PaddC Q c) | PX P i Q => PX P i (PaddC Q c) end. Fixpoint PsubC (P:Pol) (c:C) : Pol := match P with | Pc c1 => Pc (c1 -! c) | Pinj j Q => Pinj j (PsubC Q c) | PX P i Q => PX P i (PsubC Q c) end. Section PopI. Variable Pop : Pol -> Pol -> Pol. Variable Q : Pol. Fixpoint PaddI (j:positive) (P:Pol) : Pol := match P with | Pc c => mkPinj j (PaddC Q c) | Pinj j' Q' => match Z.pos_sub j' j with | Zpos k => mkPinj j (Pop (Pinj k Q') Q) | Z0 => mkPinj j (Pop Q' Q) | Zneg k => mkPinj j' (PaddI k Q') end | PX P i Q' => match j with | xH => PX P i (Pop Q' Q) | xO j => PX P i (PaddI (Pos.pred_double j) Q') | xI j => PX P i (PaddI (xO j) Q') end end. Fixpoint PsubI (j:positive) (P:Pol) : Pol := match P with | Pc c => mkPinj j (PaddC (--Q) c) | Pinj j' Q' => match Z.pos_sub j' j with | Zpos k => mkPinj j (Pop (Pinj k Q') Q) | Z0 => mkPinj j (Pop Q' Q) | Zneg k => mkPinj j' (PsubI k Q') end | PX P i Q' => match j with | xH => PX P i (Pop Q' Q) | xO j => PX P i (PsubI (Pos.pred_double j) Q') | xI j => PX P i (PsubI (xO j) Q') end end. Variable P' : Pol. Fixpoint PaddX (i':positive) (P:Pol) : Pol := match P with | Pc c => PX P' i' P | Pinj j Q' => match j with | xH => PX P' i' Q' | xO j => PX P' i' (Pinj (Pos.pred_double j) Q') | xI j => PX P' i' (Pinj (xO j) Q') end | PX P i Q' => match Z.pos_sub i i' with | Zpos k => mkPX (Pop (PX P k P0) P') i' Q' | Z0 => mkPX (Pop P P') i Q' | Zneg k => mkPX (PaddX k P) i Q' end end. Fixpoint PsubX (i':positive) (P:Pol) : Pol := match P with | Pc c => PX (--P') i' P | Pinj j Q' => match j with | xH => PX (--P') i' Q' | xO j => PX (--P') i' (Pinj (Pos.pred_double j) Q') | xI j => PX (--P') i' (Pinj (xO j) Q') end | PX P i Q' => match Z.pos_sub i i' with | Zpos k => mkPX (Pop (PX P k P0) P') i' Q' | Z0 => mkPX (Pop P P') i Q' | Zneg k => mkPX (PsubX k P) i Q' end end. End PopI. Fixpoint Padd (P P': Pol) {struct P'} : Pol := match P' with | Pc c' => PaddC P c' | Pinj j' Q' => PaddI Padd Q' j' P | PX P' i' Q' => match P with | Pc c => PX P' i' (PaddC Q' c) | Pinj j Q => match j with | xH => PX P' i' (Padd Q Q') | xO j => PX P' i' (Padd (Pinj (Pos.pred_double j) Q) Q') | xI j => PX P' i' (Padd (Pinj (xO j) Q) Q') end | PX P i Q => match Z.pos_sub i i' with | Zpos k => mkPX (Padd (PX P k P0) P') i' (Padd Q Q') | Z0 => mkPX (Padd P P') i (Padd Q Q') | Zneg k => mkPX (PaddX Padd P' k P) i (Padd Q Q') end end end. Infix "++" := Padd. Fixpoint Psub (P P': Pol) {struct P'} : Pol := match P' with | Pc c' => PsubC P c' | Pinj j' Q' => PsubI Psub Q' j' P | PX P' i' Q' => match P with | Pc c => PX (--P') i' (*(--(PsubC Q' c))*) (PaddC (--Q') c) | Pinj j Q => match j with | xH => PX (--P') i' (Psub Q Q') | xO j => PX (--P') i' (Psub (Pinj (Pos.pred_double j) Q) Q') | xI j => PX (--P') i' (Psub (Pinj (xO j) Q) Q') end | PX P i Q => match Z.pos_sub i i' with | Zpos k => mkPX (Psub (PX P k P0) P') i' (Psub Q Q') | Z0 => mkPX (Psub P P') i (Psub Q Q') | Zneg k => mkPX (PsubX Psub P' k P) i (Psub Q Q') end end end. Infix "--" := Psub. (** Multiplication *) Fixpoint PmulC_aux (P:Pol) (c:C) : Pol := match P with | Pc c' => Pc (c' *! c) | Pinj j Q => mkPinj j (PmulC_aux Q c) | PX P i Q => mkPX (PmulC_aux P c) i (PmulC_aux Q c) end. Definition PmulC P c := if c ?=! cO then P0 else if c ?=! cI then P else PmulC_aux P c. Section PmulI. Variable Pmul : Pol -> Pol -> Pol. Variable Q : Pol. Fixpoint PmulI (j:positive) (P:Pol) : Pol := match P with | Pc c => mkPinj j (PmulC Q c) | Pinj j' Q' => match Z.pos_sub j' j with | Zpos k => mkPinj j (Pmul (Pinj k Q') Q) | Z0 => mkPinj j (Pmul Q' Q) | Zneg k => mkPinj j' (PmulI k Q') end | PX P' i' Q' => match j with | xH => mkPX (PmulI xH P') i' (Pmul Q' Q) | xO j' => mkPX (PmulI j P') i' (PmulI (Pos.pred_double j') Q') | xI j' => mkPX (PmulI j P') i' (PmulI (xO j') Q') end end. End PmulI. Fixpoint Pmul (P P'' : Pol) {struct P''} : Pol := match P'' with | Pc c => PmulC P c | Pinj j' Q' => PmulI Pmul Q' j' P | PX P' i' Q' => match P with | Pc c => PmulC P'' c | Pinj j Q => let QQ' := match j with | xH => Pmul Q Q' | xO j => Pmul (Pinj (Pos.pred_double j) Q) Q' | xI j => Pmul (Pinj (xO j) Q) Q' end in mkPX (Pmul P P') i' QQ' | PX P i Q=> let QQ' := Pmul Q Q' in let PQ' := PmulI Pmul Q' xH P in let QP' := Pmul (mkPinj xH Q) P' in let PP' := Pmul P P' in (mkPX (mkPX PP' i P0 ++ QP') i' P0) ++ mkPX PQ' i QQ' end end. Infix "**" := Pmul. (** Monomial **) (** A monomial is X1^k1...Xi^ki. Its representation is a simplified version of the polynomial representation: - [mon0] correspond to the polynom [P1]. - [(zmon j M)] corresponds to [(Pinj j ...)], i.e. skip j variable indices. - [(vmon i M)] is X^i*M with X the current variable, its corresponds to (PX P1 i ...)] *) Inductive Mon: Set := | mon0: Mon | zmon: positive -> Mon -> Mon | vmon: positive -> Mon -> Mon. Definition mkZmon j M := match M with mon0 => mon0 | _ => zmon j M end. Definition zmon_pred j M := match j with xH => M | _ => mkZmon (Pos.pred j) M end. Definition mkVmon i M := match M with | mon0 => vmon i mon0 | zmon j m => vmon i (zmon_pred j m) | vmon i' m => vmon (i+i') m end. Fixpoint CFactor (P: Pol) (c: C) {struct P}: Pol * Pol := match P with | Pc c1 => let (q,r) := cdiv c1 c in (Pc r, Pc q) | Pinj j1 P1 => let (R,S) := CFactor P1 c in (mkPinj j1 R, mkPinj j1 S) | PX P1 i Q1 => let (R1, S1) := CFactor P1 c in let (R2, S2) := CFactor Q1 c in (mkPX R1 i R2, mkPX S1 i S2) end. Fixpoint MFactor (P: Pol) (c: C) (M: Mon) {struct P}: Pol * Pol := match P, M with _, mon0 => if (ceqb c cI) then (Pc cO, P) else CFactor P c | Pc _, _ => (P, Pc cO) | Pinj j1 P1, zmon j2 M1 => match j1 ?= j2 with Eq => let (R,S) := MFactor P1 c M1 in (mkPinj j1 R, mkPinj j1 S) | Lt => let (R,S) := MFactor P1 c (zmon (j2 - j1) M1) in (mkPinj j1 R, mkPinj j1 S) | Gt => (P, Pc cO) end | Pinj _ _, vmon _ _ => (P, Pc cO) | PX P1 i Q1, zmon j M1 => let M2 := zmon_pred j M1 in let (R1, S1) := MFactor P1 c M in let (R2, S2) := MFactor Q1 c M2 in (mkPX R1 i R2, mkPX S1 i S2) | PX P1 i Q1, vmon j M1 => match i ?= j with Eq => let (R1,S1) := MFactor P1 c (mkZmon xH M1) in (mkPX R1 i Q1, S1) | Lt => let (R1,S1) := MFactor P1 c (vmon (j - i) M1) in (mkPX R1 i Q1, S1) | Gt => let (R1,S1) := MFactor P1 c (mkZmon xH M1) in (mkPX R1 i Q1, mkPX S1 (i-j) (Pc cO)) end end. Definition POneSubst (P1: Pol) (cM1: C * Mon) (P2: Pol): option Pol := let (c,M1) := cM1 in let (Q1,R1) := MFactor P1 c M1 in match R1 with (Pc c) => if c ?=! cO then None else Some (Padd Q1 (Pmul P2 R1)) | _ => Some (Padd Q1 (Pmul P2 R1)) end. Fixpoint PNSubst1 (P1: Pol) (cM1: C * Mon) (P2: Pol) (n: nat) : Pol := match POneSubst P1 cM1 P2 with Some P3 => match n with S n1 => PNSubst1 P3 cM1 P2 n1 | _ => P3 end | _ => P1 end. Definition PNSubst (P1: Pol) (cM1: C * Mon) (P2: Pol) (n: nat): option Pol := match POneSubst P1 cM1 P2 with Some P3 => match n with S n1 => Some (PNSubst1 P3 cM1 P2 n1) | _ => None end | _ => None end. Fixpoint PSubstL1 (P1: Pol) (LM1: list ((C * Mon) * Pol)) (n: nat) : Pol := match LM1 with cons (M1,P2) LM2 => PSubstL1 (PNSubst1 P1 M1 P2 n) LM2 n | _ => P1 end. Fixpoint PSubstL (P1: Pol) (LM1: list ((C * Mon) * Pol)) (n: nat) : option Pol := match LM1 with cons (M1,P2) LM2 => match PNSubst P1 M1 P2 n with Some P3 => Some (PSubstL1 P3 LM2 n) | None => PSubstL P1 LM2 n end | _ => None end. Fixpoint PNSubstL (P1: Pol) (LM1: list ((C * Mon) * Pol)) (m n: nat) : Pol := match PSubstL P1 LM1 n with Some P3 => match m with S m1 => PNSubstL P3 LM1 m1 n | _ => P3 end | _ => P1 end. (** Evaluation of a polynomial towards R *) Local Notation hd := (List.hd 0). Fixpoint Pphi(l:list R) (P:Pol) : R := match P with | Pc c => [c] | Pinj j Q => Pphi (jump j l) Q | PX P i Q => Pphi l P * (hd l) ^ i + Pphi (tail l) Q end. Reserved Notation "P @ l " (at level 10, no associativity). Notation "P @ l " := (Pphi l P). Definition Pequiv (P Q : Pol) := forall l, P@l == Q@l. Infix "===" := Pequiv (at level 70, no associativity). Instance Pequiv_eq : Equivalence Pequiv. Proof. unfold Pequiv; split; red; intros; [reflexivity|now symmetry|now etransitivity]. Qed. Instance Pphi_ext : Proper (eq ==> Pequiv ==> req) Pphi. Proof. now intros l l' <- P Q H. Qed. Instance Pinj_ext : Proper (eq ==> Pequiv ==> Pequiv) Pinj. Proof. intros i j <- P P' HP l. simpl. now rewrite HP. Qed. Instance PX_ext : Proper (Pequiv ==> eq ==> Pequiv ==> Pequiv) PX. Proof. intros P P' HP p p' <- Q Q' HQ l. simpl. now rewrite HP, HQ. Qed. (** Evaluation of a monomial towards R *) Fixpoint Mphi(l:list R) (M: Mon) : R := match M with | mon0 => rI | zmon j M1 => Mphi (jump j l) M1 | vmon i M1 => Mphi (tail l) M1 * (hd l) ^ i end. Notation "M @@ l" := (Mphi l M) (at level 10, no associativity). (** Proofs *) Ltac destr_pos_sub := match goal with |- context [Z.pos_sub ?x ?y] => generalize (Z.pos_sub_discr x y); destruct (Z.pos_sub x y) end. Lemma jump_add' i j (l:list R) : jump (i + j) l = jump j (jump i l). Proof. rewrite Pos.add_comm. apply jump_add. Qed. Lemma Peq_ok P P' : (P ?== P') = true -> P === P'. Proof. unfold Pequiv. revert P';induction P;destruct P';simpl; intros H l; try easy. - now apply (morph_eq CRmorph). - destruct (Pos.compare_spec p p0); [ subst | easy | easy ]. now rewrite IHP. - specialize (IHP1 P'1); specialize (IHP2 P'2). destruct (Pos.compare_spec p p0); [ subst | easy | easy ]. destruct (P2 ?== P'1); [|easy]. rewrite H in *. now rewrite IHP1, IHP2. Qed. Lemma Peq_spec P P' : BoolSpec (P === P') True (P ?== P'). Proof. generalize (Peq_ok P P'). destruct (P ?== P'); auto. Qed. Lemma Pphi0 l : P0@l == 0. Proof. simpl;apply (morph0 CRmorph). Qed. Lemma Pphi1 l : P1@l == 1. Proof. simpl;apply (morph1 CRmorph). Qed. Lemma mkPinj_ok j l P : (mkPinj j P)@l == P@(jump j l). Proof. destruct P;simpl;rsimpl. now rewrite jump_add'. Qed. Instance mkPinj_ext : Proper (eq ==> Pequiv ==> Pequiv) mkPinj. Proof. intros i j <- P Q H l. now rewrite !mkPinj_ok. Qed. Lemma pow_pos_add x i j : x^(j + i) == x^i * x^j. Proof. rewrite Pos.add_comm. apply (pow_pos_add Rsth Reqe.(Rmul_ext) ARth.(ARmul_assoc)). Qed. Lemma ceqb_spec c c' : BoolSpec ([c] == [c']) True (c ?=! c'). Proof. generalize (morph_eq CRmorph c c'). destruct (c ?=! c'); auto. Qed. Lemma mkPX_ok l P i Q : (mkPX P i Q)@l == P@l * (hd l)^i + Q@(tail l). Proof. unfold mkPX. destruct P. - case ceqb_spec; intros H; simpl; try reflexivity. rewrite H, (morph0 CRmorph), mkPinj_ok; rsimpl. - reflexivity. - case Peq_spec; intros H; simpl; try reflexivity. rewrite H, Pphi0, Pos.add_comm, pow_pos_add; rsimpl. Qed. Instance mkPX_ext : Proper (Pequiv ==> eq ==> Pequiv ==> Pequiv) mkPX. Proof. intros P P' HP i i' <- Q Q' HQ l. now rewrite !mkPX_ok, HP, HQ. Qed. Hint Rewrite Pphi0 Pphi1 mkPinj_ok mkPX_ok (morph0 CRmorph) (morph1 CRmorph) (morph0 CRmorph) (morph_add CRmorph) (morph_mul CRmorph) (morph_sub CRmorph) (morph_opp CRmorph) : Esimpl. (* Quicker than autorewrite with Esimpl :-) *) Ltac Esimpl := try rewrite_db Esimpl; rsimpl; simpl. Lemma PaddC_ok c P l : (PaddC P c)@l == P@l + [c]. Proof. revert l;induction P;simpl;intros;Esimpl;trivial. rewrite IHP2;rsimpl. Qed. Lemma PsubC_ok c P l : (PsubC P c)@l == P@l - [c]. Proof. revert l;induction P;simpl;intros. - Esimpl. - rewrite IHP;rsimpl. - rewrite IHP2;rsimpl. Qed. Lemma PmulC_aux_ok c P l : (PmulC_aux P c)@l == P@l * [c]. Proof. revert l;induction P;simpl;intros;Esimpl;trivial. rewrite IHP1, IHP2;rsimpl. add_permut. mul_permut. Qed. Lemma PmulC_ok c P l : (PmulC P c)@l == P@l * [c]. Proof. unfold PmulC. case ceqb_spec; intros H. - rewrite H; Esimpl. - case ceqb_spec; intros H'. + rewrite H'; Esimpl. + apply PmulC_aux_ok. Qed. Lemma Popp_ok P l : (--P)@l == - P@l. Proof. revert l;induction P;simpl;intros. - Esimpl. - apply IHP. - rewrite IHP1, IHP2;rsimpl. Qed. Hint Rewrite PaddC_ok PsubC_ok PmulC_ok Popp_ok : Esimpl. Lemma PaddX_ok P' P k l : (forall P l, (P++P')@l == P@l + P'@l) -> (PaddX Padd P' k P) @ l == P@l + P'@l * (hd l)^k. Proof. intros IHP'. revert k l. induction P;simpl;intros. - add_permut. - destruct p; simpl; rewrite ?jump_pred_double; add_permut. - destr_pos_sub; intros ->; Esimpl. + rewrite IHP';rsimpl. add_permut. + rewrite IHP', pow_pos_add;simpl;Esimpl. add_permut. + rewrite IHP1, pow_pos_add;rsimpl. add_permut. Qed. Lemma Padd_ok P' P l : (P ++ P')@l == P@l + P'@l. Proof. revert P l; induction P';simpl;intros;Esimpl. - revert p l; induction P;simpl;intros. + Esimpl; add_permut. + destr_pos_sub; intros ->;Esimpl. * now rewrite IHP'. * rewrite IHP';Esimpl. now rewrite jump_add'. * rewrite IHP. now rewrite jump_add'. + destruct p0;simpl. * rewrite IHP2;simpl. rsimpl. * rewrite IHP2;simpl. rewrite jump_pred_double. rsimpl. * rewrite IHP'. rsimpl. - destruct P;simpl. + Esimpl. add_permut. + destruct p0;simpl;Esimpl; rewrite IHP'2; simpl. * rsimpl. add_permut. * rewrite jump_pred_double. rsimpl. add_permut. * rsimpl. add_permut. + destr_pos_sub; intros ->; Esimpl. * rewrite IHP'1, IHP'2;rsimpl. add_permut. * rewrite IHP'1, IHP'2;simpl;Esimpl. rewrite pow_pos_add;rsimpl. add_permut. * rewrite PaddX_ok by trivial; rsimpl. rewrite IHP'2, pow_pos_add; rsimpl. add_permut. Qed. Lemma Psub_opp P' P : P -- P' === P ++ (--P'). Proof. revert P; induction P'; simpl; intros. - intro l; Esimpl. - revert p; induction P; simpl; intros; try reflexivity. + destr_pos_sub; intros ->; now apply mkPinj_ext. + destruct p0; now apply PX_ext. - destruct P; simpl; try reflexivity. + destruct p0; now apply PX_ext. + destr_pos_sub; intros ->; apply mkPX_ext; auto. revert p1. induction P2; simpl; intros; try reflexivity. destr_pos_sub; intros ->; now apply mkPX_ext. Qed. Lemma Psub_ok P' P l : (P -- P')@l == P@l - P'@l. Proof. rewrite Psub_opp, Padd_ok, Popp_ok. rsimpl. Qed. Lemma PmulI_ok P' : (forall P l, (Pmul P P') @ l == P @ l * P' @ l) -> forall P p l, (PmulI Pmul P' p P) @ l == P @ l * P' @ (jump p l). Proof. intros IHP'. induction P;simpl;intros. - Esimpl; mul_permut. - destr_pos_sub; intros ->;Esimpl. + now rewrite IHP'. + now rewrite IHP', jump_add'. + now rewrite IHP, jump_add'. - destruct p0;Esimpl; rewrite ?IHP1, ?IHP2; rsimpl. + f_equiv. mul_permut. + rewrite jump_pred_double. f_equiv. mul_permut. + rewrite IHP'. f_equiv. mul_permut. Qed. Lemma Pmul_ok P P' l : (P**P')@l == P@l * P'@l. Proof. revert P l;induction P';simpl;intros. - apply PmulC_ok. - apply PmulI_ok;trivial. - destruct P. + rewrite (ARmul_comm ARth). Esimpl. + Esimpl. f_equiv. rewrite IHP'1; Esimpl. destruct p0;rewrite IHP'2;Esimpl. rewrite jump_pred_double; Esimpl. + rewrite Padd_ok, !mkPX_ok, Padd_ok, !mkPX_ok, !IHP'1, !IHP'2, PmulI_ok; trivial. simpl. Esimpl. add_permut; f_equiv; mul_permut. Qed. Lemma mkZmon_ok M j l : (mkZmon j M) @@ l == (zmon j M) @@ l. Proof. destruct M; simpl; rsimpl. Qed. Lemma zmon_pred_ok M j l : (zmon_pred j M) @@ (tail l) == (zmon j M) @@ l. Proof. destruct j; simpl; rewrite ?mkZmon_ok; simpl; rsimpl. rewrite jump_pred_double; rsimpl. Qed. Lemma mkVmon_ok M i l : (mkVmon i M)@@l == M@@l * (hd l)^i. Proof. destruct M;simpl;intros;rsimpl. - rewrite zmon_pred_ok;simpl;rsimpl. - rewrite pow_pos_add;rsimpl. Qed. Ltac destr_factor := match goal with | H : context [CFactor ?P _] |- context [CFactor ?P ?c] => destruct (CFactor P c); destr_factor; rewrite H; clear H | H : context [MFactor ?P _ _] |- context [MFactor ?P ?c ?M] => specialize (H M); destruct (MFactor P c M); destr_factor; rewrite H; clear H | _ => idtac end. Lemma Mcphi_ok P c l : let (Q,R) := CFactor P c in P@l == Q@l + [c] * R@l. Proof. revert l. induction P as [c0 | j P IH | P1 IH1 i P2 IH2]; intros l; Esimpl. - assert (H := div_th.(div_eucl_th) c0 c). destruct cdiv as (q,r). rewrite H; Esimpl. add_permut. - destr_factor. Esimpl. - destr_factor. Esimpl. add_permut. Qed. Lemma Mphi_ok P (cM: C * Mon) l : let (c,M) := cM in let (Q,R) := MFactor P c M in P@l == Q@l + [c] * M@@l * R@l. Proof. destruct cM as (c,M). revert M l. induction P; destruct M; intros l; simpl; auto; try (case ceqb_spec; intro He); try (case Pos.compare_spec; intros He); rewrite ?He; destr_factor; simpl; Esimpl. - assert (H := div_th.(div_eucl_th) c0 c). destruct cdiv as (q,r). rewrite H; Esimpl. add_permut. - assert (H := Mcphi_ok P c). destr_factor. Esimpl. - now rewrite <- jump_add, Pos.sub_add. - assert (H2 := Mcphi_ok P2 c). assert (H3 := Mcphi_ok P3 c). destr_factor. Esimpl. add_permut. - rewrite zmon_pred_ok. simpl. add_permut. - rewrite mkZmon_ok. simpl. add_permut. mul_permut. - add_permut. mul_permut. rewrite <- pow_pos_add, Pos.add_comm, Pos.sub_add by trivial; rsimpl. - rewrite mkZmon_ok. simpl. Esimpl. add_permut. mul_permut. rewrite <- pow_pos_add, Pos.sub_add by trivial; rsimpl. Qed. Lemma POneSubst_ok P1 cM1 P2 P3 l : POneSubst P1 cM1 P2 = Some P3 -> [fst cM1] * (snd cM1)@@l == P2@l -> P1@l == P3@l. Proof. destruct cM1 as (cc,M1). unfold POneSubst. assert (H := Mphi_ok P1 (cc, M1) l). simpl in H. destruct MFactor as (R1,S1); simpl. rewrite H. clear H. intros EQ EQ'. replace P3 with (R1 ++ P2 ** S1). - rewrite EQ', Padd_ok, Pmul_ok; rsimpl. - revert EQ. destruct S1; try now injection 1. case ceqb_spec; now inversion 2. Qed. Lemma PNSubst1_ok n P1 cM1 P2 l : [fst cM1] * (snd cM1)@@l == P2@l -> P1@l == (PNSubst1 P1 cM1 P2 n)@l. Proof. revert P1. induction n; simpl; intros P1; generalize (POneSubst_ok P1 cM1 P2); destruct POneSubst; intros; rewrite <- ?IHn; auto; reflexivity. Qed. Lemma PNSubst_ok n P1 cM1 P2 l P3 : PNSubst P1 cM1 P2 n = Some P3 -> [fst cM1] * (snd cM1)@@l == P2@l -> P1@l == P3@l. Proof. unfold PNSubst. assert (H := POneSubst_ok P1 cM1 P2); destruct POneSubst; try discriminate. destruct n; inversion_clear 1. intros. rewrite <- PNSubst1_ok; auto. Qed. Fixpoint MPcond (LM1: list (C * Mon * Pol)) (l: list R) : Prop := match LM1 with | (M1,P2) :: LM2 => ([fst M1] * (snd M1)@@l == P2@l) /\ MPcond LM2 l | _ => True end. Lemma PSubstL1_ok n LM1 P1 l : MPcond LM1 l -> P1@l == (PSubstL1 P1 LM1 n)@l. Proof. revert P1; induction LM1 as [|(M2,P2) LM2 IH]; simpl; intros. - reflexivity. - rewrite <- IH by intuition; now apply PNSubst1_ok. Qed. Lemma PSubstL_ok n LM1 P1 P2 l : PSubstL P1 LM1 n = Some P2 -> MPcond LM1 l -> P1@l == P2@l. Proof. revert P1. induction LM1 as [|(M2,P2') LM2 IH]; simpl; intros. - discriminate. - assert (H':=PNSubst_ok n P3 M2 P2'). destruct PNSubst. * injection H as <-. rewrite <- PSubstL1_ok; intuition. * now apply IH. Qed. Lemma PNSubstL_ok m n LM1 P1 l : MPcond LM1 l -> P1@l == (PNSubstL P1 LM1 m n)@l. Proof. revert LM1 P1. induction m; simpl; intros; assert (H' := PSubstL_ok n LM1 P2); destruct PSubstL; auto; try reflexivity. rewrite <- IHm; auto. Qed. (** Definition of polynomial expressions *) Inductive PExpr : Type := | PEO : PExpr | PEI : PExpr | PEc : C -> PExpr | PEX : positive -> PExpr | PEadd : PExpr -> PExpr -> PExpr | PEsub : PExpr -> PExpr -> PExpr | PEmul : PExpr -> PExpr -> PExpr | PEopp : PExpr -> PExpr | PEpow : PExpr -> N -> PExpr. (** evaluation of polynomial expressions towards R *) Definition mk_X j := mkPinj_pred j mkX. (** evaluation of polynomial expressions towards R *) Fixpoint PEeval (l:list R) (pe:PExpr) {struct pe} : R := match pe with | PEO => rO | PEI => rI | PEc c => phi c | PEX j => nth 0 j l | PEadd pe1 pe2 => (PEeval l pe1) + (PEeval l pe2) | PEsub pe1 pe2 => (PEeval l pe1) - (PEeval l pe2) | PEmul pe1 pe2 => (PEeval l pe1) * (PEeval l pe2) | PEopp pe1 => - (PEeval l pe1) | PEpow pe1 n => rpow (PEeval l pe1) (Cp_phi n) end. Strategy expand [PEeval]. (** Correctness proofs *) Lemma mkX_ok p l : nth 0 p l == (mk_X p) @ l. Proof. destruct p;simpl;intros;Esimpl;trivial. - now rewrite <-jump_tl, nth_jump. - now rewrite <- nth_jump, nth_pred_double. Qed. Hint Rewrite Padd_ok Psub_ok : Esimpl. Section POWER. Variable subst_l : Pol -> Pol. Fixpoint Ppow_pos (res P:Pol) (p:positive) : Pol := match p with | xH => subst_l (res ** P) | xO p => Ppow_pos (Ppow_pos res P p) P p | xI p => subst_l ((Ppow_pos (Ppow_pos res P p) P p) ** P) end. Definition Ppow_N P n := match n with | N0 => P1 | Npos p => Ppow_pos P1 P p end. Lemma Ppow_pos_ok l : (forall P, subst_l P@l == P@l) -> forall res P p, (Ppow_pos res P p)@l == res@l * (pow_pos Pmul P p)@l. Proof. intros subst_l_ok res P p. revert res. induction p;simpl;intros; rewrite ?subst_l_ok, ?Pmul_ok, ?IHp; mul_permut. Qed. Lemma Ppow_N_ok l : (forall P, subst_l P@l == P@l) -> forall P n, (Ppow_N P n)@l == (pow_N P1 Pmul P n)@l. Proof. destruct n;simpl. - reflexivity. - rewrite Ppow_pos_ok by trivial. Esimpl. Qed. End POWER. (** Normalization and rewriting *) Section NORM_SUBST_REC. Variable n : nat. Variable lmp:list (C*Mon*Pol). Let subst_l P := PNSubstL P lmp n n. Let Pmul_subst P1 P2 := subst_l (P1 ** P2). Let Ppow_subst := Ppow_N subst_l. Fixpoint norm_aux (pe:PExpr) : Pol := match pe with | PEO => Pc cO | PEI => Pc cI | PEc c => Pc c | PEX j => mk_X j | PEadd (PEopp pe1) pe2 => (norm_aux pe2) -- (norm_aux pe1) | PEadd pe1 (PEopp pe2) => (norm_aux pe1) -- (norm_aux pe2) | PEadd pe1 pe2 => (norm_aux pe1) ++ (norm_aux pe2) | PEsub pe1 pe2 => (norm_aux pe1) -- (norm_aux pe2) | PEmul pe1 pe2 => (norm_aux pe1) ** (norm_aux pe2) | PEopp pe1 => -- (norm_aux pe1) | PEpow pe1 n => Ppow_N (fun p => p) (norm_aux pe1) n end. Definition norm_subst pe := subst_l (norm_aux pe). (** Internally, [norm_aux] is expanded in a large number of cases. To speed-up proofs, we use an alternative definition. *) Definition get_PEopp pe := match pe with | PEopp pe' => Some pe' | _ => None end. Lemma norm_aux_PEadd pe1 pe2 : norm_aux (PEadd pe1 pe2) = match get_PEopp pe1, get_PEopp pe2 with | Some pe1', _ => (norm_aux pe2) -- (norm_aux pe1') | None, Some pe2' => (norm_aux pe1) -- (norm_aux pe2') | None, None => (norm_aux pe1) ++ (norm_aux pe2) end. Proof. simpl (norm_aux (PEadd _ _)). destruct pe1; [ | | | | | | | reflexivity | ]; destruct pe2; simpl get_PEopp; reflexivity. Qed. Lemma norm_aux_PEopp pe : match get_PEopp pe with | Some pe' => norm_aux pe = -- (norm_aux pe') | None => True end. Proof. now destruct pe. Qed. Arguments norm_aux !pe : simpl nomatch. Lemma norm_aux_spec l pe : PEeval l pe == (norm_aux pe)@l. Proof. intros. induction pe; cbn. - now rewrite (morph0 CRmorph). - now rewrite (morph1 CRmorph). - reflexivity. - apply mkX_ok. - rewrite IHpe1, IHpe2. assert (H1 := norm_aux_PEopp pe1). assert (H2 := norm_aux_PEopp pe2). rewrite norm_aux_PEadd. do 2 destruct get_PEopp; rewrite ?H1, ?H2; Esimpl; add_permut. - rewrite IHpe1, IHpe2. Esimpl. - rewrite IHpe1, IHpe2. now rewrite Pmul_ok. - rewrite IHpe. Esimpl. - rewrite Ppow_N_ok by reflexivity. rewrite pow_th.(rpow_pow_N). destruct n0; simpl; Esimpl. induction p;simpl; now rewrite ?IHp, ?IHpe, ?Pms_ok, ?Pmul_ok. Qed. Lemma norm_subst_spec : forall l pe, MPcond lmp l -> PEeval l pe == (norm_subst pe)@l. Proof. intros;unfold norm_subst. unfold subst_l;rewrite <- PNSubstL_ok;trivial. apply norm_aux_spec. Qed. End NORM_SUBST_REC. Fixpoint interp_PElist (l:list R) (lpe:list (PExpr*PExpr)) {struct lpe} : Prop := match lpe with | nil => True | (me,pe)::lpe => match lpe with | nil => PEeval l me == PEeval l pe | _ => PEeval l me == PEeval l pe /\ interp_PElist l lpe end end. Fixpoint mon_of_pol (P:Pol) : option (C * Mon) := match P with | Pc c => if (c ?=! cO) then None else Some (c, mon0) | Pinj j P => match mon_of_pol P with | None => None | Some (c,m) => Some (c, mkZmon j m) end | PX P i Q => if Peq Q P0 then match mon_of_pol P with | None => None | Some (c,m) => Some (c, mkVmon i m) end else None end. Fixpoint mk_monpol_list (lpe:list (PExpr * PExpr)) : list (C*Mon*Pol) := match lpe with | nil => nil | (me,pe)::lpe => match mon_of_pol (norm_subst 0 nil me) with | None => mk_monpol_list lpe | Some m => (m,norm_subst 0 nil pe):: mk_monpol_list lpe end end. Lemma mon_of_pol_ok : forall P m, mon_of_pol P = Some m -> forall l, [fst m] * Mphi l (snd m) == P@l. Proof. induction P;simpl;intros;Esimpl. assert (H1 := (morph_eq CRmorph) c cO). destruct (c ?=! cO). discriminate. inversion H;trivial;Esimpl. generalize H;clear H;case_eq (mon_of_pol P). intros (c1,P2) H0 H1; inversion H1; Esimpl. generalize (IHP (c1, P2) H0 (jump p l)). rewrite mkZmon_ok;simpl;auto. intros; discriminate. generalize H;clear H;change match P3 with | Pc c => c ?=! cO | Pinj _ _ => false | PX _ _ _ => false end with (P3 ?== P0). assert (H := Peq_ok P3 P0). destruct (P3 ?== P0). case_eq (mon_of_pol P2);try intros (cc, pp); intros. inversion H1. simpl. rewrite mkVmon_ok;simpl. rewrite H;trivial;Esimpl. generalize (IHP1 _ H0); simpl; intros HH; rewrite HH; rsimpl. discriminate. intros;discriminate. Qed. Lemma interp_PElist_ok : forall l lpe, interp_PElist l lpe -> MPcond (mk_monpol_list lpe) l. Proof. induction lpe;simpl. trivial. destruct a;simpl;intros. assert (HH:=mon_of_pol_ok (norm_subst 0 nil p)); destruct (mon_of_pol (norm_subst 0 nil p)). split. rewrite <- norm_subst_spec by exact I. destruct lpe;try destruct H;rewrite <- H; rewrite (norm_subst_spec 0 nil); try exact I;apply HH;trivial. apply IHlpe. destruct lpe;simpl;trivial. destruct H. exact H0. apply IHlpe. destruct lpe;simpl;trivial. destruct H. exact H0. Qed. Lemma norm_subst_ok : forall n l lpe pe, interp_PElist l lpe -> PEeval l pe == (norm_subst n (mk_monpol_list lpe) pe)@l. Proof. intros;apply norm_subst_spec. apply interp_PElist_ok;trivial. Qed. Lemma ring_correct : forall n l lpe pe1 pe2, interp_PElist l lpe -> (let lmp := mk_monpol_list lpe in norm_subst n lmp pe1 ?== norm_subst n lmp pe2) = true -> PEeval l pe1 == PEeval l pe2. Proof. simpl;intros. do 2 (rewrite (norm_subst_ok n l lpe);trivial). apply Peq_ok;trivial. Qed. (** Generic evaluation of polynomial towards R avoiding parenthesis *) Variable get_sign : C -> option C. Variable get_sign_spec : sign_theory copp ceqb get_sign. Section EVALUATION. (* [mkpow x p] = x^p *) Variable mkpow : R -> positive -> R. (* [mkpow x p] = -(x^p) *) Variable mkopp_pow : R -> positive -> R. (* [mkmult_pow r x p] = r * x^p *) Variable mkmult_pow : R -> R -> positive -> R. Fixpoint mkmult_rec (r:R) (lm:list (R*positive)) {struct lm}: R := match lm with | nil => r | cons (x,p) t => mkmult_rec (mkmult_pow r x p) t end. Definition mkmult1 lm := match lm with | nil => 1 | cons (x,p) t => mkmult_rec (mkpow x p) t end. Definition mkmultm1 lm := match lm with | nil => ropp rI | cons (x,p) t => mkmult_rec (mkopp_pow x p) t end. Definition mkmult_c_pos c lm := if c ?=! cI then mkmult1 (rev' lm) else mkmult_rec [c] (rev' lm). Definition mkmult_c c lm := match get_sign c with | None => mkmult_c_pos c lm | Some c' => if c' ?=! cI then mkmultm1 (rev' lm) else mkmult_rec [c] (rev' lm) end. Definition mkadd_mult rP c lm := match get_sign c with | None => rP + mkmult_c_pos c lm | Some c' => rP - mkmult_c_pos c' lm end. Definition add_pow_list (r:R) n l := match n with | N0 => l | Npos p => (r,p)::l end. Fixpoint add_mult_dev (rP:R) (P:Pol) (fv:list R) (n:N) (lm:list (R*positive)) {struct P} : R := match P with | Pc c => let lm := add_pow_list (hd fv) n lm in mkadd_mult rP c lm | Pinj j Q => add_mult_dev rP Q (jump j fv) N0 (add_pow_list (hd fv) n lm) | PX P i Q => let rP := add_mult_dev rP P fv (N.add (Npos i) n) lm in if Q ?== P0 then rP else add_mult_dev rP Q (tail fv) N0 (add_pow_list (hd fv) n lm) end. Fixpoint mult_dev (P:Pol) (fv : list R) (n:N) (lm:list (R*positive)) {struct P} : R := (* P@l * (hd 0 l)^n * lm *) match P with | Pc c => mkmult_c c (add_pow_list (hd fv) n lm) | Pinj j Q => mult_dev Q (jump j fv) N0 (add_pow_list (hd fv) n lm) | PX P i Q => let rP := mult_dev P fv (N.add (Npos i) n) lm in if Q ?== P0 then rP else let lmq := add_pow_list (hd fv) n lm in add_mult_dev rP Q (tail fv) N0 lmq end. Definition Pphi_avoid fv P := mult_dev P fv N0 nil. Fixpoint r_list_pow (l:list (R*positive)) : R := match l with | nil => rI | cons (r,p) l => pow_pos rmul r p * r_list_pow l end. Hypothesis mkpow_spec : forall r p, mkpow r p == pow_pos rmul r p. Hypothesis mkopp_pow_spec : forall r p, mkopp_pow r p == - (pow_pos rmul r p). Hypothesis mkmult_pow_spec : forall r x p, mkmult_pow r x p == r * pow_pos rmul x p. Lemma mkmult_rec_ok : forall lm r, mkmult_rec r lm == r * r_list_pow lm. Proof. induction lm;intros;simpl;Esimpl. destruct a as (x,p);Esimpl. rewrite IHlm. rewrite mkmult_pow_spec. Esimpl. Qed. Lemma mkmult1_ok : forall lm, mkmult1 lm == r_list_pow lm. Proof. destruct lm;simpl;Esimpl. destruct p. rewrite mkmult_rec_ok;rewrite mkpow_spec;Esimpl. Qed. Lemma mkmultm1_ok : forall lm, mkmultm1 lm == - r_list_pow lm. Proof. destruct lm;simpl;Esimpl. destruct p;rewrite mkmult_rec_ok. rewrite mkopp_pow_spec;Esimpl. Qed. Lemma r_list_pow_rev : forall l, r_list_pow (rev' l) == r_list_pow l. Proof. assert (forall l lr : list (R * positive), r_list_pow (rev_append l lr) == r_list_pow lr * r_list_pow l). induction l;intros;simpl;Esimpl. destruct a;rewrite IHl;Esimpl. rewrite (ARmul_comm ARth (pow_pos rmul r p)). reflexivity. intros;unfold rev'. rewrite H;simpl;Esimpl. Qed. Lemma mkmult_c_pos_ok : forall c lm, mkmult_c_pos c lm == [c]* r_list_pow lm. Proof. intros;unfold mkmult_c_pos;simpl. assert (H := (morph_eq CRmorph) c cI). rewrite <- r_list_pow_rev; destruct (c ?=! cI). rewrite H;trivial;Esimpl. apply mkmult1_ok. apply mkmult_rec_ok. Qed. Lemma mkmult_c_ok : forall c lm, mkmult_c c lm == [c] * r_list_pow lm. Proof. intros;unfold mkmult_c;simpl. case_eq (get_sign c);intros. assert (H1 := (morph_eq CRmorph) c0 cI). destruct (c0 ?=! cI). rewrite (CRmorph.(morph_eq) _ _ (get_sign_spec.(sign_spec) _ H)). Esimpl. rewrite H1;trivial. rewrite <- r_list_pow_rev;trivial;Esimpl. apply mkmultm1_ok. rewrite <- r_list_pow_rev; apply mkmult_rec_ok. apply mkmult_c_pos_ok. Qed. Lemma mkadd_mult_ok : forall rP c lm, mkadd_mult rP c lm == rP + [c]*r_list_pow lm. Proof. intros;unfold mkadd_mult. case_eq (get_sign c);intros. rewrite (CRmorph.(morph_eq) _ _ (get_sign_spec.(sign_spec) _ H));Esimpl. rewrite mkmult_c_pos_ok;Esimpl. rewrite mkmult_c_pos_ok;Esimpl. Qed. Lemma add_pow_list_ok : forall r n l, r_list_pow (add_pow_list r n l) == pow_N rI rmul r n * r_list_pow l. Proof. destruct n;simpl;intros;Esimpl. Qed. Lemma add_mult_dev_ok : forall P rP fv n lm, add_mult_dev rP P fv n lm == rP + P@fv*pow_N rI rmul (hd fv) n * r_list_pow lm. Proof. induction P;simpl;intros. rewrite mkadd_mult_ok. rewrite add_pow_list_ok; Esimpl. rewrite IHP. simpl. rewrite add_pow_list_ok; Esimpl. change (match P3 with | Pc c => c ?=! cO | Pinj _ _ => false | PX _ _ _ => false end) with (Peq P3 P0). change match n with | N0 => Npos p | Npos q => Npos (p + q) end with (N.add (Npos p) n);trivial. assert (H := Peq_ok P3 P0). destruct (P3 ?== P0). rewrite (H eq_refl). rewrite IHP1. destruct n;simpl;Esimpl;rewrite pow_pos_add;Esimpl. add_permut. mul_permut. rewrite IHP2. rewrite IHP1. destruct n;simpl;Esimpl;rewrite pow_pos_add;Esimpl. add_permut. mul_permut. Qed. Lemma mult_dev_ok : forall P fv n lm, mult_dev P fv n lm == P@fv * pow_N rI rmul (hd fv) n * r_list_pow lm. Proof. induction P;simpl;intros;Esimpl. rewrite mkmult_c_ok;rewrite add_pow_list_ok;Esimpl. rewrite IHP. simpl;rewrite add_pow_list_ok;Esimpl. change (match P3 with | Pc c => c ?=! cO | Pinj _ _ => false | PX _ _ _ => false end) with (Peq P3 P0). change match n with | N0 => Npos p | Npos q => Npos (p + q) end with (N.add (Npos p) n);trivial. assert (H := Peq_ok P3 P0). destruct (P3 ?== P0). rewrite (H eq_refl). rewrite IHP1. destruct n;simpl;Esimpl;rewrite pow_pos_add;Esimpl. mul_permut. rewrite add_mult_dev_ok. rewrite IHP1; rewrite add_pow_list_ok. destruct n;simpl;Esimpl;rewrite pow_pos_add;Esimpl. add_permut; mul_permut. Qed. Lemma Pphi_avoid_ok : forall P fv, Pphi_avoid fv P == P@fv. Proof. unfold Pphi_avoid;intros;rewrite mult_dev_ok;simpl;Esimpl. Qed. End EVALUATION. Definition Pphi_pow := let mkpow x p := match p with xH => x | _ => rpow x (Cp_phi (Npos p)) end in let mkopp_pow x p := ropp (mkpow x p) in let mkmult_pow r x p := rmul r (mkpow x p) in Pphi_avoid mkpow mkopp_pow mkmult_pow. Lemma local_mkpow_ok r p : match p with | xI _ => rpow r (Cp_phi (Npos p)) | xO _ => rpow r (Cp_phi (Npos p)) | 1 => r end == pow_pos rmul r p. Proof. destruct p; now rewrite ?pow_th.(rpow_pow_N). Qed. Lemma Pphi_pow_ok : forall P fv, Pphi_pow fv P == P@fv. Proof. unfold Pphi_pow;intros;apply Pphi_avoid_ok;intros; now rewrite ?local_mkpow_ok. Qed. Lemma ring_rw_pow_correct : forall n lH l, interp_PElist l lH -> forall lmp, mk_monpol_list lH = lmp -> forall pe npe, norm_subst n lmp pe = npe -> PEeval l pe == Pphi_pow l npe. Proof. intros n lH l H1 lmp Heq1 pe npe Heq2. rewrite Pphi_pow_ok, <- Heq2, <- Heq1. apply norm_subst_ok. trivial. Qed. Fixpoint mkmult_pow (r x:R) (p: positive) {struct p} : R := match p with | xH => r*x | xO p => mkmult_pow (mkmult_pow r x p) x p | xI p => mkmult_pow (mkmult_pow (r*x) x p) x p end. Definition mkpow x p := match p with | xH => x | xO p => mkmult_pow x x (Pos.pred_double p) | xI p => mkmult_pow x x (xO p) end. Definition mkopp_pow x p := match p with | xH => -x | xO p => mkmult_pow (-x) x (Pos.pred_double p) | xI p => mkmult_pow (-x) x (xO p) end. Definition Pphi_dev := Pphi_avoid mkpow mkopp_pow mkmult_pow. Lemma mkmult_pow_ok p r x : mkmult_pow r x p == r * x^p. Proof. revert r; induction p;intros;simpl;Esimpl;rewrite !IHp;Esimpl. Qed. Lemma mkpow_ok p x : mkpow x p == x^p. Proof. destruct p;simpl;intros;Esimpl. - rewrite !mkmult_pow_ok;Esimpl. - rewrite mkmult_pow_ok;Esimpl. change x with (x^1) at 1. now rewrite <- pow_pos_add, Pos.add_1_r, Pos.succ_pred_double. Qed. Lemma mkopp_pow_ok p x : mkopp_pow x p == - x^p. Proof. destruct p;simpl;intros;Esimpl. - rewrite !mkmult_pow_ok;Esimpl. - rewrite mkmult_pow_ok;Esimpl. change x with (x^1) at 1. now rewrite <- pow_pos_add, Pos.add_1_r, Pos.succ_pred_double. Qed. Lemma Pphi_dev_ok : forall P fv, Pphi_dev fv P == P@fv. Proof. unfold Pphi_dev;intros;apply Pphi_avoid_ok. - intros;apply mkpow_ok. - intros;apply mkopp_pow_ok. - intros;apply mkmult_pow_ok. Qed. Lemma ring_rw_correct : forall n lH l, interp_PElist l lH -> forall lmp, mk_monpol_list lH = lmp -> forall pe npe, norm_subst n lmp pe = npe -> PEeval l pe == Pphi_dev l npe. Proof. intros n lH l H1 lmp Heq1 pe npe Heq2. rewrite Pphi_dev_ok. rewrite <- Heq2;rewrite <- Heq1. apply norm_subst_ok. trivial. Qed. End MakeRingPol. Arguments PEO [C]. Arguments PEI [C].