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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * CNRS-Ecole Polytechnique-INRIA Futurs-Universite Paris Sud *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
Require Import List.
Require Import Peano_dec.
Require Import LegacyRing.
Require Import LegacyField_Compl.
Record Field_Theory : Type :=
{A : Type;
Aplus : A -> A -> A;
Amult : A -> A -> A;
Aone : A;
Azero : A;
Aopp : A -> A;
Aeq : A -> A -> bool;
Ainv : A -> A;
Aminus : option (A -> A -> A);
Adiv : option (A -> A -> A);
RT : Ring_Theory Aplus Amult Aone Azero Aopp Aeq;
Th_inv_def : forall n:A, n <> Azero -> Amult (Ainv n) n = Aone}.
(* The reflexion structure *)
Inductive ExprA : Set :=
| EAzero : ExprA
| EAone : ExprA
| EAplus : ExprA -> ExprA -> ExprA
| EAmult : ExprA -> ExprA -> ExprA
| EAopp : ExprA -> ExprA
| EAinv : ExprA -> ExprA
| EAvar : nat -> ExprA.
(**** Decidability of equality ****)
Lemma eqExprA_O : forall e1 e2:ExprA, {e1 = e2} + {e1 <> e2}.
Proof.
double induction e1 e2; try intros;
try (left; reflexivity) || (try (right; discriminate)).
elim (H1 e0); intro y; elim (H2 e); intro y0;
try
(left; rewrite y; rewrite y0; auto) ||
(right; red in |- *; intro; inversion H3; auto).
elim (H1 e0); intro y; elim (H2 e); intro y0;
try
(left; rewrite y; rewrite y0; auto) ||
(right; red in |- *; intro; inversion H3; auto).
elim (H0 e); intro y.
left; rewrite y; auto.
right; red in |- *; intro; inversion H1; auto.
elim (H0 e); intro y.
left; rewrite y; auto.
right; red in |- *; intro; inversion H1; auto.
elim (eq_nat_dec n n0); intro y.
left; rewrite y; auto.
right; red in |- *; intro; inversion H; auto.
Defined.
Definition eq_nat_dec := Eval compute in eq_nat_dec.
Definition eqExprA := Eval compute in eqExprA_O.
(**** Generation of the multiplier ****)
Fixpoint mult_of_list (e:list ExprA) : ExprA :=
match e with
| nil => EAone
| e1 :: l1 => EAmult e1 (mult_of_list l1)
end.
Section Theory_of_fields.
Variable T : Field_Theory.
Let AT := A T.
Let AplusT := Aplus T.
Let AmultT := Amult T.
Let AoneT := Aone T.
Let AzeroT := Azero T.
Let AoppT := Aopp T.
Let AeqT := Aeq T.
Let AinvT := Ainv T.
Let RTT := RT T.
Let Th_inv_defT := Th_inv_def T.
Add Legacy Abstract Ring (A T) (Aplus T) (Amult T) (Aone T) (
Azero T) (Aopp T) (Aeq T) (RT T).
Add Legacy Abstract Ring AT AplusT AmultT AoneT AzeroT AoppT AeqT RTT.
(***************************)
(* Lemmas to be used *)
(***************************)
Lemma AplusT_comm : forall r1 r2:AT, AplusT r1 r2 = AplusT r2 r1.
Proof.
intros; legacy ring.
Qed.
Lemma AplusT_assoc :
forall r1 r2 r3:AT, AplusT (AplusT r1 r2) r3 = AplusT r1 (AplusT r2 r3).
Proof.
intros; legacy ring.
Qed.
Lemma AmultT_comm : forall r1 r2:AT, AmultT r1 r2 = AmultT r2 r1.
Proof.
intros; legacy ring.
Qed.
Lemma AmultT_assoc :
forall r1 r2 r3:AT, AmultT (AmultT r1 r2) r3 = AmultT r1 (AmultT r2 r3).
Proof.
intros; legacy ring.
Qed.
Lemma AplusT_Ol : forall r:AT, AplusT AzeroT r = r.
Proof.
intros; legacy ring.
Qed.
Lemma AmultT_1l : forall r:AT, AmultT AoneT r = r.
Proof.
intros; legacy ring.
Qed.
Lemma AplusT_AoppT_r : forall r:AT, AplusT r (AoppT r) = AzeroT.
Proof.
intros; legacy ring.
Qed.
Lemma AmultT_AplusT_distr :
forall r1 r2 r3:AT,
AmultT r1 (AplusT r2 r3) = AplusT (AmultT r1 r2) (AmultT r1 r3).
Proof.
intros; legacy ring.
Qed.
Lemma r_AplusT_plus : forall r r1 r2:AT, AplusT r r1 = AplusT r r2 -> r1 = r2.
Proof.
intros; transitivity (AplusT (AplusT (AoppT r) r) r1).
legacy ring.
transitivity (AplusT (AplusT (AoppT r) r) r2).
repeat rewrite AplusT_assoc; rewrite <- H; reflexivity.
legacy ring.
Qed.
Lemma r_AmultT_mult :
forall r r1 r2:AT, AmultT r r1 = AmultT r r2 -> r <> AzeroT -> r1 = r2.
Proof.
intros; transitivity (AmultT (AmultT (AinvT r) r) r1).
rewrite Th_inv_defT; [ symmetry in |- *; apply AmultT_1l; auto | auto ].
transitivity (AmultT (AmultT (AinvT r) r) r2).
repeat rewrite AmultT_assoc; rewrite H; trivial.
rewrite Th_inv_defT; [ apply AmultT_1l; auto | auto ].
Qed.
Lemma AmultT_Or : forall r:AT, AmultT r AzeroT = AzeroT.
Proof.
intro; legacy ring.
Qed.
Lemma AmultT_Ol : forall r:AT, AmultT AzeroT r = AzeroT.
Proof.
intro; legacy ring.
Qed.
Lemma AmultT_1r : forall r:AT, AmultT r AoneT = r.
Proof.
intro; legacy ring.
Qed.
Lemma AinvT_r : forall r:AT, r <> AzeroT -> AmultT r (AinvT r) = AoneT.
Proof.
intros; rewrite AmultT_comm; apply Th_inv_defT; auto.
Qed.
Lemma Rmult_neq_0_reg :
forall r1 r2:AT, AmultT r1 r2 <> AzeroT -> r1 <> AzeroT /\ r2 <> AzeroT.
Proof.
intros r1 r2 H; split; red in |- *; intro; apply H; rewrite H0; legacy ring.
Qed.
(************************)
(* Interpretation *)
(************************)
(**** ExprA --> A ****)
Fixpoint interp_ExprA (lvar:list (AT * nat)) (e:ExprA) {struct e} :
AT :=
match e with
| EAzero => AzeroT
| EAone => AoneT
| EAplus e1 e2 => AplusT (interp_ExprA lvar e1) (interp_ExprA lvar e2)
| EAmult e1 e2 => AmultT (interp_ExprA lvar e1) (interp_ExprA lvar e2)
| EAopp e => Aopp T (interp_ExprA lvar e)
| EAinv e => Ainv T (interp_ExprA lvar e)
| EAvar n => assoc_2nd AT nat eq_nat_dec lvar n AzeroT
end.
(************************)
(* Simplification *)
(************************)
(**** Associativity ****)
Definition merge_mult :=
(fix merge_mult (e1:ExprA) : ExprA -> ExprA :=
fun e2:ExprA =>
match e1 with
| EAmult t1 t2 =>
match t2 with
| EAmult t2 t3 => EAmult t1 (EAmult t2 (merge_mult t3 e2))
| _ => EAmult t1 (EAmult t2 e2)
end
| _ => EAmult e1 e2
end).
Fixpoint assoc_mult (e:ExprA) : ExprA :=
match e with
| EAmult e1 e3 =>
match e1 with
| EAmult e1 e2 =>
merge_mult (merge_mult (assoc_mult e1) (assoc_mult e2))
(assoc_mult e3)
| _ => EAmult e1 (assoc_mult e3)
end
| _ => e
end.
Definition merge_plus :=
(fix merge_plus (e1:ExprA) : ExprA -> ExprA :=
fun e2:ExprA =>
match e1 with
| EAplus t1 t2 =>
match t2 with
| EAplus t2 t3 => EAplus t1 (EAplus t2 (merge_plus t3 e2))
| _ => EAplus t1 (EAplus t2 e2)
end
| _ => EAplus e1 e2
end).
Fixpoint assoc (e:ExprA) : ExprA :=
match e with
| EAplus e1 e3 =>
match e1 with
| EAplus e1 e2 =>
merge_plus (merge_plus (assoc e1) (assoc e2)) (assoc e3)
| _ => EAplus (assoc_mult e1) (assoc e3)
end
| _ => assoc_mult e
end.
Lemma merge_mult_correct1 :
forall (e1 e2 e3:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (merge_mult (EAmult e1 e2) e3) =
interp_ExprA lvar (EAmult e1 (merge_mult e2 e3)).
Proof.
intros e1 e2; generalize e1; generalize e2; clear e1 e2.
simple induction e2; auto; intros.
unfold merge_mult at 1 in |- *; fold merge_mult in |- *;
unfold interp_ExprA at 2 in |- *; fold interp_ExprA in |- *;
rewrite (H0 e e3 lvar); unfold interp_ExprA at 1 in |- *;
fold interp_ExprA in |- *; unfold interp_ExprA at 5 in |- *;
fold interp_ExprA in |- *; auto.
Qed.
Lemma merge_mult_correct :
forall (e1 e2:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (merge_mult e1 e2) = interp_ExprA lvar (EAmult e1 e2).
Proof.
simple induction e1; auto; intros.
elim e0; try (intros; simpl in |- *; legacy ring).
unfold interp_ExprA in H2; fold interp_ExprA in H2;
cut
(AmultT (interp_ExprA lvar e2)
(AmultT (interp_ExprA lvar e4)
(AmultT (interp_ExprA lvar e) (interp_ExprA lvar e3))) =
AmultT
(AmultT (AmultT (interp_ExprA lvar e) (interp_ExprA lvar e4))
(interp_ExprA lvar e2)) (interp_ExprA lvar e3)).
intro H3; rewrite H3; rewrite <- H2; rewrite merge_mult_correct1;
simpl in |- *; legacy ring.
legacy ring.
Qed.
Lemma assoc_mult_correct1 :
forall (e1 e2:ExprA) (lvar:list (AT * nat)),
AmultT (interp_ExprA lvar (assoc_mult e1))
(interp_ExprA lvar (assoc_mult e2)) =
interp_ExprA lvar (assoc_mult (EAmult e1 e2)).
Proof.
simple induction e1; auto; intros.
rewrite <- (H e0 lvar); simpl in |- *; rewrite merge_mult_correct;
simpl in |- *; rewrite merge_mult_correct; simpl in |- *;
auto.
Qed.
Lemma assoc_mult_correct :
forall (e:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (assoc_mult e) = interp_ExprA lvar e.
Proof.
simple induction e; auto; intros.
elim e0; intros.
intros; simpl in |- *; legacy ring.
simpl in |- *; rewrite (AmultT_1l (interp_ExprA lvar (assoc_mult e1)));
rewrite (AmultT_1l (interp_ExprA lvar e1)); apply H0.
simpl in |- *; rewrite (H0 lvar); auto.
simpl in |- *; rewrite merge_mult_correct; simpl in |- *;
rewrite merge_mult_correct; simpl in |- *; rewrite AmultT_assoc;
rewrite assoc_mult_correct1; rewrite H2; simpl in |- *;
rewrite <- assoc_mult_correct1 in H1; unfold interp_ExprA at 3 in H1;
fold interp_ExprA in H1; rewrite (H0 lvar) in H1;
rewrite (AmultT_comm (interp_ExprA lvar e3) (interp_ExprA lvar e1));
rewrite <- AmultT_assoc; rewrite H1; rewrite AmultT_assoc;
legacy ring.
simpl in |- *; rewrite (H0 lvar); auto.
simpl in |- *; rewrite (H0 lvar); auto.
simpl in |- *; rewrite (H0 lvar); auto.
Qed.
Lemma merge_plus_correct1 :
forall (e1 e2 e3:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (merge_plus (EAplus e1 e2) e3) =
interp_ExprA lvar (EAplus e1 (merge_plus e2 e3)).
Proof.
intros e1 e2; generalize e1; generalize e2; clear e1 e2.
simple induction e2; auto; intros.
unfold merge_plus at 1 in |- *; fold merge_plus in |- *;
unfold interp_ExprA at 2 in |- *; fold interp_ExprA in |- *;
rewrite (H0 e e3 lvar); unfold interp_ExprA at 1 in |- *;
fold interp_ExprA in |- *; unfold interp_ExprA at 5 in |- *;
fold interp_ExprA in |- *; auto.
Qed.
Lemma merge_plus_correct :
forall (e1 e2:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (merge_plus e1 e2) = interp_ExprA lvar (EAplus e1 e2).
Proof.
simple induction e1; auto; intros.
elim e0; try intros; try (simpl in |- *; legacy ring).
unfold interp_ExprA in H2; fold interp_ExprA in H2;
cut
(AplusT (interp_ExprA lvar e2)
(AplusT (interp_ExprA lvar e4)
(AplusT (interp_ExprA lvar e) (interp_ExprA lvar e3))) =
AplusT
(AplusT (AplusT (interp_ExprA lvar e) (interp_ExprA lvar e4))
(interp_ExprA lvar e2)) (interp_ExprA lvar e3)).
intro H3; rewrite H3; rewrite <- H2; rewrite merge_plus_correct1;
simpl in |- *; legacy ring.
legacy ring.
Qed.
Lemma assoc_plus_correct :
forall (e1 e2:ExprA) (lvar:list (AT * nat)),
AplusT (interp_ExprA lvar (assoc e1)) (interp_ExprA lvar (assoc e2)) =
interp_ExprA lvar (assoc (EAplus e1 e2)).
Proof.
simple induction e1; auto; intros.
rewrite <- (H e0 lvar); simpl in |- *; rewrite merge_plus_correct;
simpl in |- *; rewrite merge_plus_correct; simpl in |- *;
auto.
Qed.
Lemma assoc_correct :
forall (e:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (assoc e) = interp_ExprA lvar e.
Proof.
simple induction e; auto; intros.
elim e0; intros.
simpl in |- *; rewrite (H0 lvar); auto.
simpl in |- *; rewrite (H0 lvar); auto.
simpl in |- *; rewrite merge_plus_correct; simpl in |- *;
rewrite merge_plus_correct; simpl in |- *; rewrite AplusT_assoc;
rewrite assoc_plus_correct; rewrite H2; simpl in |- *;
apply
(r_AplusT_plus (interp_ExprA lvar (assoc e1))
(AplusT (interp_ExprA lvar (assoc e2))
(AplusT (interp_ExprA lvar e3) (interp_ExprA lvar e1)))
(AplusT (AplusT (interp_ExprA lvar e2) (interp_ExprA lvar e3))
(interp_ExprA lvar e1))); rewrite <- AplusT_assoc;
rewrite
(AplusT_comm (interp_ExprA lvar (assoc e1)) (interp_ExprA lvar (assoc e2)))
; rewrite assoc_plus_correct; rewrite H1; simpl in |- *;
rewrite (H0 lvar);
rewrite <-
(AplusT_assoc (AplusT (interp_ExprA lvar e2) (interp_ExprA lvar e1))
(interp_ExprA lvar e3) (interp_ExprA lvar e1))
;
rewrite
(AplusT_assoc (interp_ExprA lvar e2) (interp_ExprA lvar e1)
(interp_ExprA lvar e3));
rewrite (AplusT_comm (interp_ExprA lvar e1) (interp_ExprA lvar e3));
rewrite <-
(AplusT_assoc (interp_ExprA lvar e2) (interp_ExprA lvar e3)
(interp_ExprA lvar e1)); apply AplusT_comm.
unfold assoc in |- *; fold assoc in |- *; unfold interp_ExprA in |- *;
fold interp_ExprA in |- *; rewrite assoc_mult_correct;
rewrite (H0 lvar); simpl in |- *; auto.
simpl in |- *; rewrite (H0 lvar); auto.
simpl in |- *; rewrite (H0 lvar); auto.
simpl in |- *; rewrite (H0 lvar); auto.
unfold assoc in |- *; fold assoc in |- *; unfold interp_ExprA in |- *;
fold interp_ExprA in |- *; rewrite assoc_mult_correct;
simpl in |- *; auto.
Qed.
(**** Distribution *****)
Fixpoint distrib_EAopp (e:ExprA) : ExprA :=
match e with
| EAplus e1 e2 => EAplus (distrib_EAopp e1) (distrib_EAopp e2)
| EAmult e1 e2 => EAmult (distrib_EAopp e1) (distrib_EAopp e2)
| EAopp e => EAmult (EAopp EAone) (distrib_EAopp e)
| e => e
end.
Definition distrib_mult_right :=
(fix distrib_mult_right (e1:ExprA) : ExprA -> ExprA :=
fun e2:ExprA =>
match e1 with
| EAplus t1 t2 =>
EAplus (distrib_mult_right t1 e2) (distrib_mult_right t2 e2)
| _ => EAmult e1 e2
end).
Fixpoint distrib_mult_left (e1 e2:ExprA) {struct e1} : ExprA :=
match e1 with
| EAplus t1 t2 =>
EAplus (distrib_mult_left t1 e2) (distrib_mult_left t2 e2)
| _ => distrib_mult_right e2 e1
end.
Fixpoint distrib_main (e:ExprA) : ExprA :=
match e with
| EAmult e1 e2 => distrib_mult_left (distrib_main e1) (distrib_main e2)
| EAplus e1 e2 => EAplus (distrib_main e1) (distrib_main e2)
| EAopp e => EAopp (distrib_main e)
| _ => e
end.
Definition distrib (e:ExprA) : ExprA := distrib_main (distrib_EAopp e).
Lemma distrib_mult_right_correct :
forall (e1 e2:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (distrib_mult_right e1 e2) =
AmultT (interp_ExprA lvar e1) (interp_ExprA lvar e2).
Proof.
simple induction e1; try intros; simpl in |- *; auto.
rewrite AmultT_comm; rewrite AmultT_AplusT_distr; rewrite (H e2 lvar);
rewrite (H0 e2 lvar); legacy ring.
Qed.
Lemma distrib_mult_left_correct :
forall (e1 e2:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (distrib_mult_left e1 e2) =
AmultT (interp_ExprA lvar e1) (interp_ExprA lvar e2).
Proof.
simple induction e1; try intros; simpl in |- *.
rewrite AmultT_Ol; rewrite distrib_mult_right_correct; simpl in |- *;
apply AmultT_Or.
rewrite distrib_mult_right_correct; simpl in |- *; apply AmultT_comm.
rewrite AmultT_comm;
rewrite
(AmultT_AplusT_distr (interp_ExprA lvar e2) (interp_ExprA lvar e)
(interp_ExprA lvar e0));
rewrite (AmultT_comm (interp_ExprA lvar e2) (interp_ExprA lvar e));
rewrite (AmultT_comm (interp_ExprA lvar e2) (interp_ExprA lvar e0));
rewrite (H e2 lvar); rewrite (H0 e2 lvar); auto.
rewrite distrib_mult_right_correct; simpl in |- *; apply AmultT_comm.
rewrite distrib_mult_right_correct; simpl in |- *; apply AmultT_comm.
rewrite distrib_mult_right_correct; simpl in |- *; apply AmultT_comm.
rewrite distrib_mult_right_correct; simpl in |- *; apply AmultT_comm.
Qed.
Lemma distrib_correct :
forall (e:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (distrib e) = interp_ExprA lvar e.
Proof.
simple induction e; intros; auto.
simpl in |- *; rewrite <- (H lvar); rewrite <- (H0 lvar);
unfold distrib in |- *; simpl in |- *; auto.
simpl in |- *; rewrite <- (H lvar); rewrite <- (H0 lvar);
unfold distrib in |- *; simpl in |- *; apply distrib_mult_left_correct.
simpl in |- *; fold AoppT in |- *; rewrite <- (H lvar);
unfold distrib in |- *; simpl in |- *; rewrite distrib_mult_right_correct;
simpl in |- *; fold AoppT in |- *; legacy ring.
Qed.
(**** Multiplication by the inverse product ****)
Lemma mult_eq :
forall (e1 e2 a:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar a <> AzeroT ->
interp_ExprA lvar (EAmult a e1) = interp_ExprA lvar (EAmult a e2) ->
interp_ExprA lvar e1 = interp_ExprA lvar e2.
Proof.
simpl in |- *; intros;
apply
(r_AmultT_mult (interp_ExprA lvar a) (interp_ExprA lvar e1)
(interp_ExprA lvar e2)); assumption.
Qed.
Fixpoint multiply_aux (a e:ExprA) {struct e} : ExprA :=
match e with
| EAplus e1 e2 => EAplus (EAmult a e1) (multiply_aux a e2)
| _ => EAmult a e
end.
Definition multiply (e:ExprA) : ExprA :=
match e with
| EAmult a e1 => multiply_aux a e1
| _ => e
end.
Lemma multiply_aux_correct :
forall (a e:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (multiply_aux a e) =
AmultT (interp_ExprA lvar a) (interp_ExprA lvar e).
Proof.
simple induction e; simpl in |- *; intros; try rewrite merge_mult_correct;
auto.
simpl in |- *; rewrite (H0 lvar); legacy ring.
Qed.
Lemma multiply_correct :
forall (e:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar (multiply e) = interp_ExprA lvar e.
Proof.
simple induction e; simpl in |- *; auto.
intros; apply multiply_aux_correct.
Qed.
(**** Permutations and simplification ****)
Fixpoint monom_remove (a m:ExprA) {struct m} : ExprA :=
match m with
| EAmult m0 m1 =>
match eqExprA m0 (EAinv a) with
| left _ => m1
| right _ => EAmult m0 (monom_remove a m1)
end
| _ =>
match eqExprA m (EAinv a) with
| left _ => EAone
| right _ => EAmult a m
end
end.
Definition monom_simplif_rem :=
(fix monom_simplif_rem (a:ExprA) : ExprA -> ExprA :=
fun m:ExprA =>
match a with
| EAmult a0 a1 => monom_simplif_rem a1 (monom_remove a0 m)
| _ => monom_remove a m
end).
Definition monom_simplif (a m:ExprA) : ExprA :=
match m with
| EAmult a' m' =>
match eqExprA a a' with
| left _ => monom_simplif_rem a m'
| right _ => m
end
| _ => m
end.
Fixpoint inverse_simplif (a e:ExprA) {struct e} : ExprA :=
match e with
| EAplus e1 e2 => EAplus (monom_simplif a e1) (inverse_simplif a e2)
| _ => monom_simplif a e
end.
Lemma monom_remove_correct :
forall (e a:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar a <> AzeroT ->
interp_ExprA lvar (monom_remove a e) =
AmultT (interp_ExprA lvar a) (interp_ExprA lvar e).
Proof.
simple induction e; intros.
simpl in |- *; case (eqExprA EAzero (EAinv a)); intros;
[ inversion e0 | simpl in |- *; trivial ].
simpl in |- *; case (eqExprA EAone (EAinv a)); intros;
[ inversion e0 | simpl in |- *; trivial ].
simpl in |- *; case (eqExprA (EAplus e0 e1) (EAinv a)); intros;
[ inversion e2 | simpl in |- *; trivial ].
simpl in |- *; case (eqExprA e0 (EAinv a)); intros.
rewrite e2; simpl in |- *; fold AinvT in |- *.
rewrite <-
(AmultT_assoc (interp_ExprA lvar a) (AinvT (interp_ExprA lvar a))
(interp_ExprA lvar e1)); rewrite AinvT_r; [ legacy ring | assumption ].
simpl in |- *; rewrite H0; auto; legacy ring.
simpl in |- *; fold AoppT in |- *; case (eqExprA (EAopp e0) (EAinv a));
intros; [ inversion e1 | simpl in |- *; trivial ].
unfold monom_remove in |- *; case (eqExprA (EAinv e0) (EAinv a)); intros.
case (eqExprA e0 a); intros.
rewrite e2; simpl in |- *; fold AinvT in |- *; rewrite AinvT_r; auto.
inversion e1; simpl in |- *; exfalso; auto.
simpl in |- *; trivial.
unfold monom_remove in |- *; case (eqExprA (EAvar n) (EAinv a)); intros;
[ inversion e0 | simpl in |- *; trivial ].
Qed.
Lemma monom_simplif_rem_correct :
forall (a e:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar a <> AzeroT ->
interp_ExprA lvar (monom_simplif_rem a e) =
AmultT (interp_ExprA lvar a) (interp_ExprA lvar e).
Proof.
simple induction a; simpl in |- *; intros; try rewrite monom_remove_correct;
auto.
elim (Rmult_neq_0_reg (interp_ExprA lvar e) (interp_ExprA lvar e0) H1);
intros.
rewrite (H0 (monom_remove e e1) lvar H3); rewrite monom_remove_correct; auto.
legacy ring.
Qed.
Lemma monom_simplif_correct :
forall (e a:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar a <> AzeroT ->
interp_ExprA lvar (monom_simplif a e) = interp_ExprA lvar e.
Proof.
simple induction e; intros; auto.
simpl in |- *; case (eqExprA a e0); intros.
rewrite <- e2; apply monom_simplif_rem_correct; auto.
simpl in |- *; trivial.
Qed.
Lemma inverse_correct :
forall (e a:ExprA) (lvar:list (AT * nat)),
interp_ExprA lvar a <> AzeroT ->
interp_ExprA lvar (inverse_simplif a e) = interp_ExprA lvar e.
Proof.
simple induction e; intros; auto.
simpl in |- *; rewrite (H0 a lvar H1); rewrite monom_simplif_correct; auto.
unfold inverse_simplif in |- *; rewrite monom_simplif_correct; auto.
Qed.
End Theory_of_fields.
(* Compatibility *)
Notation AplusT_sym := AplusT_comm (only parsing).
Notation AmultT_sym := AmultT_comm (only parsing).
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