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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2010 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
(* $Id$ *)
Require Import LegacyRing_theory.
Require Import Quote.
Set Implicit Arguments.
Unset Boxed Definitions.
Lemma index_eq_prop : forall n m:index, Is_true (index_eq n m) -> n = m.
Proof.
intros.
apply index_eq_prop.
generalize H.
case (index_eq n m); simpl in |- *; trivial; intros.
contradiction.
Qed.
Section semi_rings.
Variable A : Type.
Variable Aplus : A -> A -> A.
Variable Amult : A -> A -> A.
Variable Aone : A.
Variable Azero : A.
Variable Aeq : A -> A -> bool.
(* Section definitions. *)
(******************************************)
(* Normal abtract Polynomials *)
(******************************************)
(* DEFINITIONS :
- A varlist is a sorted product of one or more variables : x, x*y*z
- A monom is a constant, a varlist or the product of a constant by a varlist
variables. 2*x*y, x*y*z, 3 are monoms : 2*3, x*3*y, 4*x*3 are NOT.
- A canonical sum is either a monom or an ordered sum of monoms
(the order on monoms is defined later)
- A normal polynomial it either a constant or a canonical sum or a constant
plus a canonical sum
*)
(* varlist is isomorphic to (list var), but we built a special inductive
for efficiency *)
Inductive varlist : Type :=
| Nil_var : varlist
| Cons_var : index -> varlist -> varlist.
Inductive canonical_sum : Type :=
| Nil_monom : canonical_sum
| Cons_monom : A -> varlist -> canonical_sum -> canonical_sum
| Cons_varlist : varlist -> canonical_sum -> canonical_sum.
(* Order on monoms *)
(* That's the lexicographic order on varlist, extended by :
- A constant is less than every monom
- The relation between two varlist is preserved by multiplication by a
constant.
Examples :
3 < x < y
x*y < x*y*y*z
2*x*y < x*y*y*z
x*y < 54*x*y*y*z
4*x*y < 59*x*y*y*z
*)
Fixpoint varlist_eq (x y:varlist) {struct y} : bool :=
match x, y with
| Nil_var, Nil_var => true
| Cons_var i xrest, Cons_var j yrest =>
andb (index_eq i j) (varlist_eq xrest yrest)
| _, _ => false
end.
Fixpoint varlist_lt (x y:varlist) {struct y} : bool :=
match x, y with
| Nil_var, Cons_var _ _ => true
| Cons_var i xrest, Cons_var j yrest =>
if index_lt i j
then true
else andb (index_eq i j) (varlist_lt xrest yrest)
| _, _ => false
end.
(* merges two variables lists *)
Fixpoint varlist_merge (l1:varlist) : varlist -> varlist :=
match l1 with
| Cons_var v1 t1 =>
(fix vm_aux (l2:varlist) : varlist :=
match l2 with
| Cons_var v2 t2 =>
if index_lt v1 v2
then Cons_var v1 (varlist_merge t1 l2)
else Cons_var v2 (vm_aux t2)
| Nil_var => l1
end)
| Nil_var => fun l2 => l2
end.
(* returns the sum of two canonical sums *)
Fixpoint canonical_sum_merge (s1:canonical_sum) :
canonical_sum -> canonical_sum :=
match s1 with
| Cons_monom c1 l1 t1 =>
(fix csm_aux (s2:canonical_sum) : canonical_sum :=
match s2 with
| Cons_monom c2 l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus c1 c2) l1 (canonical_sum_merge t1 t2)
else
if varlist_lt l1 l2
then Cons_monom c1 l1 (canonical_sum_merge t1 s2)
else Cons_monom c2 l2 (csm_aux t2)
| Cons_varlist l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus c1 Aone) l1 (canonical_sum_merge t1 t2)
else
if varlist_lt l1 l2
then Cons_monom c1 l1 (canonical_sum_merge t1 s2)
else Cons_varlist l2 (csm_aux t2)
| Nil_monom => s1
end)
| Cons_varlist l1 t1 =>
(fix csm_aux2 (s2:canonical_sum) : canonical_sum :=
match s2 with
| Cons_monom c2 l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus Aone c2) l1 (canonical_sum_merge t1 t2)
else
if varlist_lt l1 l2
then Cons_varlist l1 (canonical_sum_merge t1 s2)
else Cons_monom c2 l2 (csm_aux2 t2)
| Cons_varlist l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus Aone Aone) l1 (canonical_sum_merge t1 t2)
else
if varlist_lt l1 l2
then Cons_varlist l1 (canonical_sum_merge t1 s2)
else Cons_varlist l2 (csm_aux2 t2)
| Nil_monom => s1
end)
| Nil_monom => fun s2 => s2
end.
(* Insertion of a monom in a canonical sum *)
Fixpoint monom_insert (c1:A) (l1:varlist) (s2:canonical_sum) {struct s2} :
canonical_sum :=
match s2 with
| Cons_monom c2 l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus c1 c2) l1 t2
else
if varlist_lt l1 l2
then Cons_monom c1 l1 s2
else Cons_monom c2 l2 (monom_insert c1 l1 t2)
| Cons_varlist l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus c1 Aone) l1 t2
else
if varlist_lt l1 l2
then Cons_monom c1 l1 s2
else Cons_varlist l2 (monom_insert c1 l1 t2)
| Nil_monom => Cons_monom c1 l1 Nil_monom
end.
Fixpoint varlist_insert (l1:varlist) (s2:canonical_sum) {struct s2} :
canonical_sum :=
match s2 with
| Cons_monom c2 l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus Aone c2) l1 t2
else
if varlist_lt l1 l2
then Cons_varlist l1 s2
else Cons_monom c2 l2 (varlist_insert l1 t2)
| Cons_varlist l2 t2 =>
if varlist_eq l1 l2
then Cons_monom (Aplus Aone Aone) l1 t2
else
if varlist_lt l1 l2
then Cons_varlist l1 s2
else Cons_varlist l2 (varlist_insert l1 t2)
| Nil_monom => Cons_varlist l1 Nil_monom
end.
(* Computes c0*s *)
Fixpoint canonical_sum_scalar (c0:A) (s:canonical_sum) {struct s} :
canonical_sum :=
match s with
| Cons_monom c l t => Cons_monom (Amult c0 c) l (canonical_sum_scalar c0 t)
| Cons_varlist l t => Cons_monom c0 l (canonical_sum_scalar c0 t)
| Nil_monom => Nil_monom
end.
(* Computes l0*s *)
Fixpoint canonical_sum_scalar2 (l0:varlist) (s:canonical_sum) {struct s} :
canonical_sum :=
match s with
| Cons_monom c l t =>
monom_insert c (varlist_merge l0 l) (canonical_sum_scalar2 l0 t)
| Cons_varlist l t =>
varlist_insert (varlist_merge l0 l) (canonical_sum_scalar2 l0 t)
| Nil_monom => Nil_monom
end.
(* Computes c0*l0*s *)
Fixpoint canonical_sum_scalar3 (c0:A) (l0:varlist)
(s:canonical_sum) {struct s} : canonical_sum :=
match s with
| Cons_monom c l t =>
monom_insert (Amult c0 c) (varlist_merge l0 l)
(canonical_sum_scalar3 c0 l0 t)
| Cons_varlist l t =>
monom_insert c0 (varlist_merge l0 l) (canonical_sum_scalar3 c0 l0 t)
| Nil_monom => Nil_monom
end.
(* returns the product of two canonical sums *)
Fixpoint canonical_sum_prod (s1 s2:canonical_sum) {struct s1} :
canonical_sum :=
match s1 with
| Cons_monom c1 l1 t1 =>
canonical_sum_merge (canonical_sum_scalar3 c1 l1 s2)
(canonical_sum_prod t1 s2)
| Cons_varlist l1 t1 =>
canonical_sum_merge (canonical_sum_scalar2 l1 s2)
(canonical_sum_prod t1 s2)
| Nil_monom => Nil_monom
end.
(* The type to represent concrete semi-ring polynomials *)
Inductive spolynomial : Type :=
| SPvar : index -> spolynomial
| SPconst : A -> spolynomial
| SPplus : spolynomial -> spolynomial -> spolynomial
| SPmult : spolynomial -> spolynomial -> spolynomial.
Fixpoint spolynomial_normalize (p:spolynomial) : canonical_sum :=
match p with
| SPvar i => Cons_varlist (Cons_var i Nil_var) Nil_monom
| SPconst c => Cons_monom c Nil_var Nil_monom
| SPplus l r =>
canonical_sum_merge (spolynomial_normalize l) (spolynomial_normalize r)
| SPmult l r =>
canonical_sum_prod (spolynomial_normalize l) (spolynomial_normalize r)
end.
(* Deletion of useless 0 and 1 in canonical sums *)
Fixpoint canonical_sum_simplify (s:canonical_sum) : canonical_sum :=
match s with
| Cons_monom c l t =>
if Aeq c Azero
then canonical_sum_simplify t
else
if Aeq c Aone
then Cons_varlist l (canonical_sum_simplify t)
else Cons_monom c l (canonical_sum_simplify t)
| Cons_varlist l t => Cons_varlist l (canonical_sum_simplify t)
| Nil_monom => Nil_monom
end.
Definition spolynomial_simplify (x:spolynomial) :=
canonical_sum_simplify (spolynomial_normalize x).
(* End definitions. *)
(* Section interpretation. *)
(*** Here a variable map is defined and the interpetation of a spolynom
acording to a certain variables map. Once again the choosen definition
is generic and could be changed ****)
Variable vm : varmap A.
(* Interpretation of list of variables
* [x1; ... ; xn ] is interpreted as (find v x1)* ... *(find v xn)
* The unbound variables are mapped to 0. Normally this case sould
* never occur. Since we want only to prove correctness theorems, which form
* is : for any varmap and any spolynom ... this is a safe and pain-saving
* choice *)
Definition interp_var (i:index) := varmap_find Azero i vm.
(* Local *) Definition ivl_aux :=
(fix ivl_aux (x:index) (t:varlist) {struct t} : A :=
match t with
| Nil_var => interp_var x
| Cons_var x' t' => Amult (interp_var x) (ivl_aux x' t')
end).
Definition interp_vl (l:varlist) :=
match l with
| Nil_var => Aone
| Cons_var x t => ivl_aux x t
end.
(* Local *) Definition interp_m (c:A) (l:varlist) :=
match l with
| Nil_var => c
| Cons_var x t => Amult c (ivl_aux x t)
end.
(* Local *) Definition ics_aux :=
(fix ics_aux (a:A) (s:canonical_sum) {struct s} : A :=
match s with
| Nil_monom => a
| Cons_varlist l t => Aplus a (ics_aux (interp_vl l) t)
| Cons_monom c l t => Aplus a (ics_aux (interp_m c l) t)
end).
(* Interpretation of a canonical sum *)
Definition interp_cs (s:canonical_sum) : A :=
match s with
| Nil_monom => Azero
| Cons_varlist l t => ics_aux (interp_vl l) t
| Cons_monom c l t => ics_aux (interp_m c l) t
end.
Fixpoint interp_sp (p:spolynomial) : A :=
match p with
| SPconst c => c
| SPvar i => interp_var i
| SPplus p1 p2 => Aplus (interp_sp p1) (interp_sp p2)
| SPmult p1 p2 => Amult (interp_sp p1) (interp_sp p2)
end.
(* End interpretation. *)
Unset Implicit Arguments.
(* Section properties. *)
Variable T : Semi_Ring_Theory Aplus Amult Aone Azero Aeq.
Hint Resolve (SR_plus_comm T).
Hint Resolve (SR_plus_assoc T).
Hint Resolve (SR_plus_assoc2 T).
Hint Resolve (SR_mult_comm T).
Hint Resolve (SR_mult_assoc T).
Hint Resolve (SR_mult_assoc2 T).
Hint Resolve (SR_plus_zero_left T).
Hint Resolve (SR_plus_zero_left2 T).
Hint Resolve (SR_mult_one_left T).
Hint Resolve (SR_mult_one_left2 T).
Hint Resolve (SR_mult_zero_left T).
Hint Resolve (SR_mult_zero_left2 T).
Hint Resolve (SR_distr_left T).
Hint Resolve (SR_distr_left2 T).
(*Hint Resolve (SR_plus_reg_left T).*)
Hint Resolve (SR_plus_permute T).
Hint Resolve (SR_mult_permute T).
Hint Resolve (SR_distr_right T).
Hint Resolve (SR_distr_right2 T).
Hint Resolve (SR_mult_zero_right T).
Hint Resolve (SR_mult_zero_right2 T).
Hint Resolve (SR_plus_zero_right T).
Hint Resolve (SR_plus_zero_right2 T).
Hint Resolve (SR_mult_one_right T).
Hint Resolve (SR_mult_one_right2 T).
(*Hint Resolve (SR_plus_reg_right T).*)
Hint Resolve refl_equal sym_equal trans_equal.
(* Hints Resolve refl_eqT sym_eqT trans_eqT. *)
Hint Immediate T.
Lemma varlist_eq_prop : forall x y:varlist, Is_true (varlist_eq x y) -> x = y.
Proof.
simple induction x; simple induction y; contradiction || (try reflexivity).
simpl in |- *; intros.
generalize (andb_prop2 _ _ H1); intros; elim H2; intros.
rewrite (index_eq_prop _ _ H3); rewrite (H v0 H4); reflexivity.
Qed.
Remark ivl_aux_ok :
forall (v:varlist) (i:index),
ivl_aux i v = Amult (interp_var i) (interp_vl v).
Proof.
simple induction v; simpl in |- *; intros.
trivial.
rewrite H; trivial.
Qed.
Lemma varlist_merge_ok :
forall x y:varlist,
interp_vl (varlist_merge x y) = Amult (interp_vl x) (interp_vl y).
Proof.
simple induction x.
simpl in |- *; trivial.
simple induction y.
simpl in |- *; trivial.
simpl in |- *; intros.
elim (index_lt i i0); simpl in |- *; intros.
repeat rewrite ivl_aux_ok.
rewrite H. simpl in |- *.
rewrite ivl_aux_ok.
eauto.
repeat rewrite ivl_aux_ok.
rewrite H0.
rewrite ivl_aux_ok.
eauto.
Qed.
Remark ics_aux_ok :
forall (x:A) (s:canonical_sum), ics_aux x s = Aplus x (interp_cs s).
Proof.
simple induction s; simpl in |- *; intros.
trivial.
reflexivity.
reflexivity.
Qed.
Remark interp_m_ok :
forall (x:A) (l:varlist), interp_m x l = Amult x (interp_vl l).
Proof.
destruct l as [| i v].
simpl in |- *; trivial.
reflexivity.
Qed.
Lemma canonical_sum_merge_ok :
forall x y:canonical_sum,
interp_cs (canonical_sum_merge x y) = Aplus (interp_cs x) (interp_cs y).
simple induction x; simpl in |- *.
trivial.
simple induction y; simpl in |- *; intros.
(* monom and nil *)
eauto.
(* monom and monom *)
generalize (varlist_eq_prop v v0).
elim (varlist_eq v v0).
intros; rewrite (H1 I).
simpl in |- *; repeat rewrite ics_aux_ok; rewrite H.
repeat rewrite interp_m_ok.
rewrite (SR_distr_left T).
repeat rewrite <- (SR_plus_assoc T).
apply f_equal with (f := Aplus (Amult a (interp_vl v0))).
trivial.
elim (varlist_lt v v0); simpl in |- *.
repeat rewrite ics_aux_ok.
rewrite H; simpl in |- *; rewrite ics_aux_ok; eauto.
rewrite ics_aux_ok; rewrite H0; repeat rewrite ics_aux_ok; simpl in |- *;
eauto.
(* monom and varlist *)
generalize (varlist_eq_prop v v0).
elim (varlist_eq v v0).
intros; rewrite (H1 I).
simpl in |- *; repeat rewrite ics_aux_ok; rewrite H.
repeat rewrite interp_m_ok.
rewrite (SR_distr_left T).
repeat rewrite <- (SR_plus_assoc T).
apply f_equal with (f := Aplus (Amult a (interp_vl v0))).
rewrite (SR_mult_one_left T).
trivial.
elim (varlist_lt v v0); simpl in |- *.
repeat rewrite ics_aux_ok.
rewrite H; simpl in |- *; rewrite ics_aux_ok; eauto.
rewrite ics_aux_ok; rewrite H0; repeat rewrite ics_aux_ok; simpl in |- *;
eauto.
simple induction y; simpl in |- *; intros.
(* varlist and nil *)
trivial.
(* varlist and monom *)
generalize (varlist_eq_prop v v0).
elim (varlist_eq v v0).
intros; rewrite (H1 I).
simpl in |- *; repeat rewrite ics_aux_ok; rewrite H.
repeat rewrite interp_m_ok.
rewrite (SR_distr_left T).
repeat rewrite <- (SR_plus_assoc T).
rewrite (SR_mult_one_left T).
apply f_equal with (f := Aplus (interp_vl v0)).
trivial.
elim (varlist_lt v v0); simpl in |- *.
repeat rewrite ics_aux_ok.
rewrite H; simpl in |- *; rewrite ics_aux_ok; eauto.
rewrite ics_aux_ok; rewrite H0; repeat rewrite ics_aux_ok; simpl in |- *;
eauto.
(* varlist and varlist *)
generalize (varlist_eq_prop v v0).
elim (varlist_eq v v0).
intros; rewrite (H1 I).
simpl in |- *; repeat rewrite ics_aux_ok; rewrite H.
repeat rewrite interp_m_ok.
rewrite (SR_distr_left T).
repeat rewrite <- (SR_plus_assoc T).
rewrite (SR_mult_one_left T).
apply f_equal with (f := Aplus (interp_vl v0)).
trivial.
elim (varlist_lt v v0); simpl in |- *.
repeat rewrite ics_aux_ok.
rewrite H; simpl in |- *; rewrite ics_aux_ok; eauto.
rewrite ics_aux_ok; rewrite H0; repeat rewrite ics_aux_ok; simpl in |- *;
eauto.
Qed.
Lemma monom_insert_ok :
forall (a:A) (l:varlist) (s:canonical_sum),
interp_cs (monom_insert a l s) =
Aplus (Amult a (interp_vl l)) (interp_cs s).
intros; generalize s; simple induction s0.
simpl in |- *; rewrite interp_m_ok; trivial.
simpl in |- *; intros.
generalize (varlist_eq_prop l v); elim (varlist_eq l v).
intro Hr; rewrite (Hr I); simpl in |- *; rewrite interp_m_ok;
repeat rewrite ics_aux_ok; rewrite interp_m_ok; rewrite (SR_distr_left T);
eauto.
elim (varlist_lt l v); simpl in |- *;
[ repeat rewrite interp_m_ok; rewrite ics_aux_ok; eauto
| repeat rewrite interp_m_ok; rewrite ics_aux_ok; rewrite H;
rewrite ics_aux_ok; eauto ].
simpl in |- *; intros.
generalize (varlist_eq_prop l v); elim (varlist_eq l v).
intro Hr; rewrite (Hr I); simpl in |- *; rewrite interp_m_ok;
repeat rewrite ics_aux_ok; rewrite (SR_distr_left T);
rewrite (SR_mult_one_left T); eauto.
elim (varlist_lt l v); simpl in |- *;
[ repeat rewrite interp_m_ok; rewrite ics_aux_ok; eauto
| repeat rewrite interp_m_ok; rewrite ics_aux_ok; rewrite H;
rewrite ics_aux_ok; eauto ].
Qed.
Lemma varlist_insert_ok :
forall (l:varlist) (s:canonical_sum),
interp_cs (varlist_insert l s) = Aplus (interp_vl l) (interp_cs s).
intros; generalize s; simple induction s0.
simpl in |- *; trivial.
simpl in |- *; intros.
generalize (varlist_eq_prop l v); elim (varlist_eq l v).
intro Hr; rewrite (Hr I); simpl in |- *; rewrite interp_m_ok;
repeat rewrite ics_aux_ok; rewrite interp_m_ok; rewrite (SR_distr_left T);
rewrite (SR_mult_one_left T); eauto.
elim (varlist_lt l v); simpl in |- *;
[ repeat rewrite interp_m_ok; rewrite ics_aux_ok; eauto
| repeat rewrite interp_m_ok; rewrite ics_aux_ok; rewrite H;
rewrite ics_aux_ok; eauto ].
simpl in |- *; intros.
generalize (varlist_eq_prop l v); elim (varlist_eq l v).
intro Hr; rewrite (Hr I); simpl in |- *; rewrite interp_m_ok;
repeat rewrite ics_aux_ok; rewrite (SR_distr_left T);
rewrite (SR_mult_one_left T); eauto.
elim (varlist_lt l v); simpl in |- *;
[ repeat rewrite interp_m_ok; rewrite ics_aux_ok; eauto
| repeat rewrite interp_m_ok; rewrite ics_aux_ok; rewrite H;
rewrite ics_aux_ok; eauto ].
Qed.
Lemma canonical_sum_scalar_ok :
forall (a:A) (s:canonical_sum),
interp_cs (canonical_sum_scalar a s) = Amult a (interp_cs s).
simple induction s.
simpl in |- *; eauto.
simpl in |- *; intros.
repeat rewrite ics_aux_ok.
repeat rewrite interp_m_ok.
rewrite H.
rewrite (SR_distr_right T).
repeat rewrite <- (SR_mult_assoc T).
reflexivity.
simpl in |- *; intros.
repeat rewrite ics_aux_ok.
repeat rewrite interp_m_ok.
rewrite H.
rewrite (SR_distr_right T).
repeat rewrite <- (SR_mult_assoc T).
reflexivity.
Qed.
Lemma canonical_sum_scalar2_ok :
forall (l:varlist) (s:canonical_sum),
interp_cs (canonical_sum_scalar2 l s) = Amult (interp_vl l) (interp_cs s).
simple induction s.
simpl in |- *; trivial.
simpl in |- *; intros.
rewrite monom_insert_ok.
repeat rewrite ics_aux_ok.
repeat rewrite interp_m_ok.
rewrite H.
rewrite varlist_merge_ok.
repeat rewrite (SR_distr_right T).
repeat rewrite <- (SR_mult_assoc T).
repeat rewrite <- (SR_plus_assoc T).
rewrite (SR_mult_permute T a (interp_vl l) (interp_vl v)).
reflexivity.
simpl in |- *; intros.
rewrite varlist_insert_ok.
repeat rewrite ics_aux_ok.
repeat rewrite interp_m_ok.
rewrite H.
rewrite varlist_merge_ok.
repeat rewrite (SR_distr_right T).
repeat rewrite <- (SR_mult_assoc T).
repeat rewrite <- (SR_plus_assoc T).
reflexivity.
Qed.
Lemma canonical_sum_scalar3_ok :
forall (c:A) (l:varlist) (s:canonical_sum),
interp_cs (canonical_sum_scalar3 c l s) =
Amult c (Amult (interp_vl l) (interp_cs s)).
simple induction s.
simpl in |- *; repeat rewrite (SR_mult_zero_right T); reflexivity.
simpl in |- *; intros.
rewrite monom_insert_ok.
repeat rewrite ics_aux_ok.
repeat rewrite interp_m_ok.
rewrite H.
rewrite varlist_merge_ok.
repeat rewrite (SR_distr_right T).
repeat rewrite <- (SR_mult_assoc T).
repeat rewrite <- (SR_plus_assoc T).
rewrite (SR_mult_permute T a (interp_vl l) (interp_vl v)).
reflexivity.
simpl in |- *; intros.
rewrite monom_insert_ok.
repeat rewrite ics_aux_ok.
repeat rewrite interp_m_ok.
rewrite H.
rewrite varlist_merge_ok.
repeat rewrite (SR_distr_right T).
repeat rewrite <- (SR_mult_assoc T).
repeat rewrite <- (SR_plus_assoc T).
rewrite (SR_mult_permute T c (interp_vl l) (interp_vl v)).
reflexivity.
Qed.
Lemma canonical_sum_prod_ok :
forall x y:canonical_sum,
interp_cs (canonical_sum_prod x y) = Amult (interp_cs x) (interp_cs y).
simple induction x; simpl in |- *; intros.
trivial.
rewrite canonical_sum_merge_ok.
rewrite canonical_sum_scalar3_ok.
rewrite ics_aux_ok.
rewrite interp_m_ok.
rewrite H.
rewrite (SR_mult_assoc T a (interp_vl v) (interp_cs y)).
symmetry in |- *.
eauto.
rewrite canonical_sum_merge_ok.
rewrite canonical_sum_scalar2_ok.
rewrite ics_aux_ok.
rewrite H.
trivial.
Qed.
Theorem spolynomial_normalize_ok :
forall p:spolynomial, interp_cs (spolynomial_normalize p) = interp_sp p.
simple induction p; simpl in |- *; intros.
reflexivity.
reflexivity.
rewrite canonical_sum_merge_ok.
rewrite H; rewrite H0.
reflexivity.
rewrite canonical_sum_prod_ok.
rewrite H; rewrite H0.
reflexivity.
Qed.
Lemma canonical_sum_simplify_ok :
forall s:canonical_sum, interp_cs (canonical_sum_simplify s) = interp_cs s.
simple induction s.
reflexivity.
(* cons_monom *)
simpl in |- *; intros.
generalize (SR_eq_prop T a Azero).
elim (Aeq a Azero).
intro Heq; rewrite (Heq I).
rewrite H.
rewrite ics_aux_ok.
rewrite interp_m_ok.
rewrite (SR_mult_zero_left T).
trivial.
intros; simpl in |- *.
generalize (SR_eq_prop T a Aone).
elim (Aeq a Aone).
intro Heq; rewrite (Heq I).
simpl in |- *.
repeat rewrite ics_aux_ok.
rewrite interp_m_ok.
rewrite H.
rewrite (SR_mult_one_left T).
reflexivity.
simpl in |- *.
repeat rewrite ics_aux_ok.
rewrite interp_m_ok.
rewrite H.
reflexivity.
(* cons_varlist *)
simpl in |- *; intros.
repeat rewrite ics_aux_ok.
rewrite H.
reflexivity.
Qed.
Theorem spolynomial_simplify_ok :
forall p:spolynomial, interp_cs (spolynomial_simplify p) = interp_sp p.
intro.
unfold spolynomial_simplify in |- *.
rewrite canonical_sum_simplify_ok.
apply spolynomial_normalize_ok.
Qed.
(* End properties. *)
End semi_rings.
Implicit Arguments Cons_varlist.
Implicit Arguments Cons_monom.
Implicit Arguments SPconst.
Implicit Arguments SPplus.
Implicit Arguments SPmult.
Section rings.
(* Here the coercion between Ring and Semi-Ring will be useful *)
Set Implicit Arguments.
Variable A : Type.
Variable Aplus : A -> A -> A.
Variable Amult : A -> A -> A.
Variable Aone : A.
Variable Azero : A.
Variable Aopp : A -> A.
Variable Aeq : A -> A -> bool.
Variable vm : varmap A.
Variable T : Ring_Theory Aplus Amult Aone Azero Aopp Aeq.
Hint Resolve (Th_plus_comm T).
Hint Resolve (Th_plus_assoc T).
Hint Resolve (Th_plus_assoc2 T).
Hint Resolve (Th_mult_comm T).
Hint Resolve (Th_mult_assoc T).
Hint Resolve (Th_mult_assoc2 T).
Hint Resolve (Th_plus_zero_left T).
Hint Resolve (Th_plus_zero_left2 T).
Hint Resolve (Th_mult_one_left T).
Hint Resolve (Th_mult_one_left2 T).
Hint Resolve (Th_mult_zero_left T).
Hint Resolve (Th_mult_zero_left2 T).
Hint Resolve (Th_distr_left T).
Hint Resolve (Th_distr_left2 T).
(*Hint Resolve (Th_plus_reg_left T).*)
Hint Resolve (Th_plus_permute T).
Hint Resolve (Th_mult_permute T).
Hint Resolve (Th_distr_right T).
Hint Resolve (Th_distr_right2 T).
Hint Resolve (Th_mult_zero_right T).
Hint Resolve (Th_mult_zero_right2 T).
Hint Resolve (Th_plus_zero_right T).
Hint Resolve (Th_plus_zero_right2 T).
Hint Resolve (Th_mult_one_right T).
Hint Resolve (Th_mult_one_right2 T).
(*Hint Resolve (Th_plus_reg_right T).*)
Hint Resolve refl_equal sym_equal trans_equal.
(*Hints Resolve refl_eqT sym_eqT trans_eqT.*)
Hint Immediate T.
(*** Definitions *)
Inductive polynomial : Type :=
| Pvar : index -> polynomial
| Pconst : A -> polynomial
| Pplus : polynomial -> polynomial -> polynomial
| Pmult : polynomial -> polynomial -> polynomial
| Popp : polynomial -> polynomial.
Fixpoint polynomial_normalize (x:polynomial) : canonical_sum A :=
match x with
| Pplus l r =>
canonical_sum_merge Aplus Aone (polynomial_normalize l)
(polynomial_normalize r)
| Pmult l r =>
canonical_sum_prod Aplus Amult Aone (polynomial_normalize l)
(polynomial_normalize r)
| Pconst c => Cons_monom c Nil_var (Nil_monom A)
| Pvar i => Cons_varlist (Cons_var i Nil_var) (Nil_monom A)
| Popp p =>
canonical_sum_scalar3 Aplus Amult Aone (Aopp Aone) Nil_var
(polynomial_normalize p)
end.
Definition polynomial_simplify (x:polynomial) :=
canonical_sum_simplify Aone Azero Aeq (polynomial_normalize x).
Fixpoint spolynomial_of (x:polynomial) : spolynomial A :=
match x with
| Pplus l r => SPplus (spolynomial_of l) (spolynomial_of r)
| Pmult l r => SPmult (spolynomial_of l) (spolynomial_of r)
| Pconst c => SPconst c
| Pvar i => SPvar A i
| Popp p => SPmult (SPconst (Aopp Aone)) (spolynomial_of p)
end.
(*** Interpretation *)
Fixpoint interp_p (p:polynomial) : A :=
match p with
| Pconst c => c
| Pvar i => varmap_find Azero i vm
| Pplus p1 p2 => Aplus (interp_p p1) (interp_p p2)
| Pmult p1 p2 => Amult (interp_p p1) (interp_p p2)
| Popp p1 => Aopp (interp_p p1)
end.
(*** Properties *)
Unset Implicit Arguments.
Lemma spolynomial_of_ok :
forall p:polynomial,
interp_p p = interp_sp Aplus Amult Azero vm (spolynomial_of p).
simple induction p; reflexivity || (simpl in |- *; intros).
rewrite H; rewrite H0; reflexivity.
rewrite H; rewrite H0; reflexivity.
rewrite H.
rewrite (Th_opp_mult_left2 T).
rewrite (Th_mult_one_left T).
reflexivity.
Qed.
Theorem polynomial_normalize_ok :
forall p:polynomial,
polynomial_normalize p =
spolynomial_normalize Aplus Amult Aone (spolynomial_of p).
simple induction p; reflexivity || (simpl in |- *; intros).
rewrite H; rewrite H0; reflexivity.
rewrite H; rewrite H0; reflexivity.
rewrite H; simpl in |- *.
elim
(canonical_sum_scalar3 Aplus Amult Aone (Aopp Aone) Nil_var
(spolynomial_normalize Aplus Amult Aone (spolynomial_of p0)));
[ reflexivity
| simpl in |- *; intros; rewrite H0; reflexivity
| simpl in |- *; intros; rewrite H0; reflexivity ].
Qed.
Theorem polynomial_simplify_ok :
forall p:polynomial,
interp_cs Aplus Amult Aone Azero vm (polynomial_simplify p) = interp_p p.
intro.
unfold polynomial_simplify in |- *.
rewrite spolynomial_of_ok.
rewrite polynomial_normalize_ok.
rewrite (canonical_sum_simplify_ok A Aplus Amult Aone Azero Aeq vm T).
rewrite (spolynomial_normalize_ok A Aplus Amult Aone Azero Aeq vm T).
reflexivity.
Qed.
End rings.
Infix "+" := Pplus : ring_scope.
Infix "*" := Pmult : ring_scope.
Notation "- x" := (Popp x) : ring_scope.
Notation "[ x ]" := (Pvar x) (at level 0) : ring_scope.
Delimit Scope ring_scope with ring.
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