(************************************************************************) (* v * The Coq Proof Assistant / The Coq Development Team *) (* n = m. Proof. simple induction n; simple induction m; simpl in |- *; try reflexivity || contradiction. intros; rewrite (H i0); trivial. intros; rewrite (H i0); trivial. Qed. Section setoid. Variable A : Type. Variable Aequiv : A -> A -> Prop. 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 S : Setoid_Theory A Aequiv. Add Setoid A Aequiv S as Asetoid. Variable plus_morph : forall a a0:A, Aequiv a a0 -> forall a1 a2:A, Aequiv a1 a2 -> Aequiv (Aplus a a1) (Aplus a0 a2). Variable mult_morph : forall a a0:A, Aequiv a a0 -> forall a1 a2:A, Aequiv a1 a2 -> Aequiv (Amult a a1) (Amult a0 a2). Variable opp_morph : forall a a0:A, Aequiv a a0 -> Aequiv (Aopp a) (Aopp a0). Add Morphism Aplus : Aplus_ext. intros; apply plus_morph; assumption. Qed. Add Morphism Amult : Amult_ext. intros; apply mult_morph; assumption. Qed. Add Morphism Aopp : Aopp_ext. exact opp_morph. Qed. Let equiv_refl := Seq_refl A Aequiv S. Let equiv_sym := Seq_sym A Aequiv S. Let equiv_trans := Seq_trans A Aequiv S. Hint Resolve equiv_refl equiv_trans. Hint Immediate equiv_sym. Section semi_setoid_rings. (* 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-setoid-ring polynomials *) Inductive setspolynomial : Type := | SetSPvar : index -> setspolynomial | SetSPconst : A -> setspolynomial | SetSPplus : setspolynomial -> setspolynomial -> setspolynomial | SetSPmult : setspolynomial -> setspolynomial -> setspolynomial. Fixpoint setspolynomial_normalize (p:setspolynomial) : canonical_sum := match p with | SetSPplus l r => canonical_sum_merge (setspolynomial_normalize l) (setspolynomial_normalize r) | SetSPmult l r => canonical_sum_prod (setspolynomial_normalize l) (setspolynomial_normalize r) | SetSPconst c => Cons_monom c Nil_var Nil_monom | SetSPvar i => Cons_varlist (Cons_var i Nil_var) Nil_monom end. 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 setspolynomial_simplify (x:setspolynomial) := canonical_sum_simplify (setspolynomial_normalize x). Variable vm : varmap A. Definition interp_var (i:index) := varmap_find Azero i vm. 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. Definition interp_m (c:A) (l:varlist) := match l with | Nil_var => c | Cons_var x t => Amult c (ivl_aux x t) end. 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). Definition interp_setcs (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_setsp (p:setspolynomial) : A := match p with | SetSPconst c => c | SetSPvar i => interp_var i | SetSPplus p1 p2 => Aplus (interp_setsp p1) (interp_setsp p2) | SetSPmult p1 p2 => Amult (interp_setsp p1) (interp_setsp p2) end. (* End interpretation. *) Unset Implicit Arguments. (* Section properties. *) Variable T : Semi_Setoid_Ring_Theory Aequiv Aplus Amult Aone Azero Aeq. Hint Resolve (SSR_plus_comm T). Hint Resolve (SSR_plus_assoc T). Hint Resolve (SSR_plus_assoc2 S T). Hint Resolve (SSR_mult_comm T). Hint Resolve (SSR_mult_assoc T). Hint Resolve (SSR_mult_assoc2 S T). Hint Resolve (SSR_plus_zero_left T). Hint Resolve (SSR_plus_zero_left2 S T). Hint Resolve (SSR_mult_one_left T). Hint Resolve (SSR_mult_one_left2 S T). Hint Resolve (SSR_mult_zero_left T). Hint Resolve (SSR_mult_zero_left2 S T). Hint Resolve (SSR_distr_left T). Hint Resolve (SSR_distr_left2 S T). Hint Resolve (SSR_plus_reg_left T). Hint Resolve (SSR_plus_permute S plus_morph T). Hint Resolve (SSR_mult_permute S mult_morph T). Hint Resolve (SSR_distr_right S plus_morph T). Hint Resolve (SSR_distr_right2 S plus_morph T). Hint Resolve (SSR_mult_zero_right S T). Hint Resolve (SSR_mult_zero_right2 S T). Hint Resolve (SSR_plus_zero_right S T). Hint Resolve (SSR_plus_zero_right2 S T). Hint Resolve (SSR_mult_one_right S T). Hint Resolve (SSR_mult_one_right2 S T). Hint Resolve (SSR_plus_reg_right S 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), Aequiv (ivl_aux i v) (Amult (interp_var i) (interp_vl v)). Proof. simple induction v; simpl in |- *; intros. trivial. rewrite (H i); trivial. Qed. Lemma varlist_merge_ok : forall x y:varlist, Aequiv (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. rewrite (ivl_aux_ok v i). rewrite (ivl_aux_ok v0 i0). rewrite (ivl_aux_ok (varlist_merge v (Cons_var i0 v0)) i). rewrite (H (Cons_var i0 v0)). simpl in |- *. rewrite (ivl_aux_ok v0 i0). eauto. rewrite (ivl_aux_ok v i). rewrite (ivl_aux_ok v0 i0). rewrite (ivl_aux_ok ((fix vm_aux (l2:varlist) : varlist := match l2 with | Nil_var => Cons_var i v | Cons_var v2 t2 => if index_lt i v2 then Cons_var i (varlist_merge v l2) else Cons_var v2 (vm_aux t2) end) v0) i0). rewrite H0. rewrite (ivl_aux_ok v i). eauto. Qed. Remark ics_aux_ok : forall (x:A) (s:canonical_sum), Aequiv (ics_aux x s) (Aplus x (interp_setcs s)). Proof. simple induction s; simpl in |- *; intros; trivial. Qed. Remark interp_m_ok : forall (x:A) (l:varlist), Aequiv (interp_m x l) (Amult x (interp_vl l)). Proof. destruct l as [| i v]; trivial. Qed. Hint Resolve ivl_aux_ok. Hint Resolve ics_aux_ok. Hint Resolve interp_m_ok. (* Hints Resolve ivl_aux_ok ics_aux_ok interp_m_ok. *) Lemma canonical_sum_merge_ok : forall x y:canonical_sum, Aequiv (interp_setcs (canonical_sum_merge x y)) (Aplus (interp_setcs x) (interp_setcs y)). Proof. simple induction x; simpl in |- *. trivial. simple induction y; simpl in |- *; intros. eauto. generalize (varlist_eq_prop v v0). elim (varlist_eq v v0). intros; rewrite (H1 I). simpl in |- *. rewrite (ics_aux_ok (interp_m a v0) c). rewrite (ics_aux_ok (interp_m a0 v0) c0). rewrite (ics_aux_ok (interp_m (Aplus a a0) v0) (canonical_sum_merge c c0)). rewrite (H c0). rewrite (interp_m_ok (Aplus a a0) v0). rewrite (interp_m_ok a v0). rewrite (interp_m_ok a0 v0). setoid_replace (Amult (Aplus a a0) (interp_vl v0)) with (Aplus (Amult a (interp_vl v0)) (Amult a0 (interp_vl v0))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (Amult a (interp_vl v0)) (Amult a0 (interp_vl v0))) (Aplus (interp_setcs c) (interp_setcs c0))) with (Aplus (Amult a (interp_vl v0)) (Aplus (Amult a0 (interp_vl v0)) (Aplus (interp_setcs c) (interp_setcs c0)))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (Amult a (interp_vl v0)) (interp_setcs c)) (Aplus (Amult a0 (interp_vl v0)) (interp_setcs c0))) with (Aplus (Amult a (interp_vl v0)) (Aplus (interp_setcs c) (Aplus (Amult a0 (interp_vl v0)) (interp_setcs c0)))); [ idtac | trivial ]. auto. elim (varlist_lt v v0); simpl in |- *. intro. rewrite (ics_aux_ok (interp_m a v) (canonical_sum_merge c (Cons_monom a0 v0 c0))) . rewrite (ics_aux_ok (interp_m a v) c). rewrite (ics_aux_ok (interp_m a0 v0) c0). rewrite (H (Cons_monom a0 v0 c0)); simpl in |- *. rewrite (ics_aux_ok (interp_m a0 v0) c0); auto. intro. rewrite (ics_aux_ok (interp_m a0 v0) ((fix csm_aux (s2:canonical_sum) : canonical_sum := match s2 with | Nil_monom => Cons_monom a v c | Cons_monom c2 l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus a c2) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_monom a v (canonical_sum_merge c s2) else Cons_monom c2 l2 (csm_aux t2) | Cons_varlist l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus a Aone) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_monom a v (canonical_sum_merge c s2) else Cons_varlist l2 (csm_aux t2) end) c0)). rewrite H0. rewrite (ics_aux_ok (interp_m a v) c); rewrite (ics_aux_ok (interp_m a0 v0) c0); simpl in |- *; auto. generalize (varlist_eq_prop v v0). elim (varlist_eq v v0). intros; rewrite (H1 I). simpl in |- *. rewrite (ics_aux_ok (interp_m (Aplus a Aone) v0) (canonical_sum_merge c c0)); rewrite (ics_aux_ok (interp_m a v0) c); rewrite (ics_aux_ok (interp_vl v0) c0). rewrite (H c0). rewrite (interp_m_ok (Aplus a Aone) v0). rewrite (interp_m_ok a v0). setoid_replace (Amult (Aplus a Aone) (interp_vl v0)) with (Aplus (Amult a (interp_vl v0)) (Amult Aone (interp_vl v0))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (Amult a (interp_vl v0)) (Amult Aone (interp_vl v0))) (Aplus (interp_setcs c) (interp_setcs c0))) with (Aplus (Amult a (interp_vl v0)) (Aplus (Amult Aone (interp_vl v0)) (Aplus (interp_setcs c) (interp_setcs c0)))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (Amult a (interp_vl v0)) (interp_setcs c)) (Aplus (interp_vl v0) (interp_setcs c0))) with (Aplus (Amult a (interp_vl v0)) (Aplus (interp_setcs c) (Aplus (interp_vl v0) (interp_setcs c0)))); [ idtac | trivial ]. setoid_replace (Amult Aone (interp_vl v0)) with (interp_vl v0); [ idtac | trivial ]. auto. elim (varlist_lt v v0); simpl in |- *. intro. rewrite (ics_aux_ok (interp_m a v) (canonical_sum_merge c (Cons_varlist v0 c0))) ; rewrite (ics_aux_ok (interp_m a v) c); rewrite (ics_aux_ok (interp_vl v0) c0). rewrite (H (Cons_varlist v0 c0)); simpl in |- *. rewrite (ics_aux_ok (interp_vl v0) c0). auto. intro. rewrite (ics_aux_ok (interp_vl v0) ((fix csm_aux (s2:canonical_sum) : canonical_sum := match s2 with | Nil_monom => Cons_monom a v c | Cons_monom c2 l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus a c2) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_monom a v (canonical_sum_merge c s2) else Cons_monom c2 l2 (csm_aux t2) | Cons_varlist l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus a Aone) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_monom a v (canonical_sum_merge c s2) else Cons_varlist l2 (csm_aux t2) end) c0)); rewrite H0. rewrite (ics_aux_ok (interp_m a v) c); rewrite (ics_aux_ok (interp_vl v0) c0); simpl in |- *. auto. simple induction y; simpl in |- *; intros. trivial. generalize (varlist_eq_prop v v0). elim (varlist_eq v v0). intros; rewrite (H1 I). simpl in |- *. rewrite (ics_aux_ok (interp_m (Aplus Aone a) v0) (canonical_sum_merge c c0)); rewrite (ics_aux_ok (interp_vl v0) c); rewrite (ics_aux_ok (interp_m a v0) c0); rewrite (H c0). rewrite (interp_m_ok (Aplus Aone a) v0); rewrite (interp_m_ok a v0). setoid_replace (Amult (Aplus Aone a) (interp_vl v0)) with (Aplus (Amult Aone (interp_vl v0)) (Amult a (interp_vl v0))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (Amult Aone (interp_vl v0)) (Amult a (interp_vl v0))) (Aplus (interp_setcs c) (interp_setcs c0))) with (Aplus (Amult Aone (interp_vl v0)) (Aplus (Amult a (interp_vl v0)) (Aplus (interp_setcs c) (interp_setcs c0)))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (interp_vl v0) (interp_setcs c)) (Aplus (Amult a (interp_vl v0)) (interp_setcs c0))) with (Aplus (interp_vl v0) (Aplus (interp_setcs c) (Aplus (Amult a (interp_vl v0)) (interp_setcs c0)))); [ idtac | trivial ]. auto. elim (varlist_lt v v0); simpl in |- *; intros. rewrite (ics_aux_ok (interp_vl v) (canonical_sum_merge c (Cons_monom a v0 c0))) ; rewrite (ics_aux_ok (interp_vl v) c); rewrite (ics_aux_ok (interp_m a v0) c0). rewrite (H (Cons_monom a v0 c0)); simpl in |- *. rewrite (ics_aux_ok (interp_m a v0) c0); auto. rewrite (ics_aux_ok (interp_m a v0) ((fix csm_aux2 (s2:canonical_sum) : canonical_sum := match s2 with | Nil_monom => Cons_varlist v c | Cons_monom c2 l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus Aone c2) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_varlist v (canonical_sum_merge c s2) else Cons_monom c2 l2 (csm_aux2 t2) | Cons_varlist l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus Aone Aone) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_varlist v (canonical_sum_merge c s2) else Cons_varlist l2 (csm_aux2 t2) end) c0)); rewrite H0. rewrite (ics_aux_ok (interp_vl v) c); rewrite (ics_aux_ok (interp_m a v0) c0); simpl in |- *; auto. generalize (varlist_eq_prop v v0). elim (varlist_eq v v0); intros. rewrite (H1 I); simpl in |- *. rewrite (ics_aux_ok (interp_m (Aplus Aone Aone) v0) (canonical_sum_merge c c0)) ; rewrite (ics_aux_ok (interp_vl v0) c); rewrite (ics_aux_ok (interp_vl v0) c0); rewrite (H c0). rewrite (interp_m_ok (Aplus Aone Aone) v0). setoid_replace (Amult (Aplus Aone Aone) (interp_vl v0)) with (Aplus (Amult Aone (interp_vl v0)) (Amult Aone (interp_vl v0))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (Amult Aone (interp_vl v0)) (Amult Aone (interp_vl v0))) (Aplus (interp_setcs c) (interp_setcs c0))) with (Aplus (Amult Aone (interp_vl v0)) (Aplus (Amult Aone (interp_vl v0)) (Aplus (interp_setcs c) (interp_setcs c0)))); [ idtac | trivial ]. setoid_replace (Aplus (Aplus (interp_vl v0) (interp_setcs c)) (Aplus (interp_vl v0) (interp_setcs c0))) with (Aplus (interp_vl v0) (Aplus (interp_setcs c) (Aplus (interp_vl v0) (interp_setcs c0)))); [ idtac | trivial ]. setoid_replace (Amult Aone (interp_vl v0)) with (interp_vl v0); auto. elim (varlist_lt v v0); simpl in |- *. rewrite (ics_aux_ok (interp_vl v) (canonical_sum_merge c (Cons_varlist v0 c0))) ; rewrite (ics_aux_ok (interp_vl v) c); rewrite (ics_aux_ok (interp_vl v0) c0); rewrite (H (Cons_varlist v0 c0)); simpl in |- *. rewrite (ics_aux_ok (interp_vl v0) c0); auto. rewrite (ics_aux_ok (interp_vl v0) ((fix csm_aux2 (s2:canonical_sum) : canonical_sum := match s2 with | Nil_monom => Cons_varlist v c | Cons_monom c2 l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus Aone c2) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_varlist v (canonical_sum_merge c s2) else Cons_monom c2 l2 (csm_aux2 t2) | Cons_varlist l2 t2 => if varlist_eq v l2 then Cons_monom (Aplus Aone Aone) v (canonical_sum_merge c t2) else if varlist_lt v l2 then Cons_varlist v (canonical_sum_merge c s2) else Cons_varlist l2 (csm_aux2 t2) end) c0)); rewrite H0. rewrite (ics_aux_ok (interp_vl v) c); rewrite (ics_aux_ok (interp_vl v0) c0); simpl in |- *; auto. Qed. Lemma monom_insert_ok : forall (a:A) (l:varlist) (s:canonical_sum), Aequiv (interp_setcs (monom_insert a l s)) (Aplus (Amult a (interp_vl l)) (interp_setcs s)). Proof. simple induction s; intros. simpl in |- *; rewrite (interp_m_ok a l); trivial. simpl in |- *; generalize (varlist_eq_prop l v); elim (varlist_eq l v). intro Hr; rewrite (Hr I); simpl in |- *. rewrite (ics_aux_ok (interp_m (Aplus a a0) v) c); rewrite (ics_aux_ok (interp_m a0 v) c). rewrite (interp_m_ok (Aplus a a0) v); rewrite (interp_m_ok a0 v). setoid_replace (Amult (Aplus a a0) (interp_vl v)) with (Aplus (Amult a (interp_vl v)) (Amult a0 (interp_vl v))); [ idtac | trivial ]. auto. elim (varlist_lt l v); simpl in |- *; intros. rewrite (ics_aux_ok (interp_m a0 v) c). rewrite (interp_m_ok a0 v); rewrite (interp_m_ok a l). auto. rewrite (ics_aux_ok (interp_m a0 v) (monom_insert a l c)); rewrite (ics_aux_ok (interp_m a0 v) c); rewrite H. auto. simpl in |- *. generalize (varlist_eq_prop l v); elim (varlist_eq l v). intro Hr; rewrite (Hr I); simpl in |- *. rewrite (ics_aux_ok (interp_m (Aplus a Aone) v) c); rewrite (ics_aux_ok (interp_vl v) c). rewrite (interp_m_ok (Aplus a Aone) v). setoid_replace (Amult (Aplus a Aone) (interp_vl v)) with (Aplus (Amult a (interp_vl v)) (Amult Aone (interp_vl v))); [ idtac | trivial ]. setoid_replace (Amult Aone (interp_vl v)) with (interp_vl v); [ idtac | trivial ]. auto. elim (varlist_lt l v); simpl in |- *; intros; auto. rewrite (ics_aux_ok (interp_vl v) (monom_insert a l c)); rewrite H. rewrite (ics_aux_ok (interp_vl v) c); auto. Qed. Lemma varlist_insert_ok : forall (l:varlist) (s:canonical_sum), Aequiv (interp_setcs (varlist_insert l s)) (Aplus (interp_vl l) (interp_setcs s)). Proof. simple induction s; simpl in |- *; intros. trivial. generalize (varlist_eq_prop l v); elim (varlist_eq l v). intro Hr; rewrite (Hr I); simpl in |- *. rewrite (ics_aux_ok (interp_m (Aplus Aone a) v) c); rewrite (ics_aux_ok (interp_m a v) c). rewrite (interp_m_ok (Aplus Aone a) v); rewrite (interp_m_ok a v). setoid_replace (Amult (Aplus Aone a) (interp_vl v)) with (Aplus (Amult Aone (interp_vl v)) (Amult a (interp_vl v))); [ idtac | trivial ]. setoid_replace (Amult Aone (interp_vl v)) with (interp_vl v); auto. elim (varlist_lt l v); simpl in |- *; intros; auto. rewrite (ics_aux_ok (interp_m a v) (varlist_insert l c)); rewrite (ics_aux_ok (interp_m a v) c). rewrite (interp_m_ok a v). rewrite H; auto. generalize (varlist_eq_prop l v); elim (varlist_eq l v). intro Hr; rewrite (Hr I); simpl in |- *. rewrite (ics_aux_ok (interp_m (Aplus Aone Aone) v) c); rewrite (ics_aux_ok (interp_vl v) c). rewrite (interp_m_ok (Aplus Aone Aone) v). setoid_replace (Amult (Aplus Aone Aone) (interp_vl v)) with (Aplus (Amult Aone (interp_vl v)) (Amult Aone (interp_vl v))); [ idtac | trivial ]. setoid_replace (Amult Aone (interp_vl v)) with (interp_vl v); auto. elim (varlist_lt l v); simpl in |- *; intros; auto. rewrite (ics_aux_ok (interp_vl v) (varlist_insert l c)). rewrite H. rewrite (ics_aux_ok (interp_vl v) c); auto. Qed. Lemma canonical_sum_scalar_ok : forall (a:A) (s:canonical_sum), Aequiv (interp_setcs (canonical_sum_scalar a s)) (Amult a (interp_setcs s)). Proof. simple induction s; simpl in |- *; intros. trivial. rewrite (ics_aux_ok (interp_m (Amult a a0) v) (canonical_sum_scalar a c)); rewrite (ics_aux_ok (interp_m a0 v) c). rewrite (interp_m_ok (Amult a a0) v); rewrite (interp_m_ok a0 v). rewrite H. setoid_replace (Amult a (Aplus (Amult a0 (interp_vl v)) (interp_setcs c))) with (Aplus (Amult a (Amult a0 (interp_vl v))) (Amult a (interp_setcs c))); [ idtac | trivial ]. auto. rewrite (ics_aux_ok (interp_m a v) (canonical_sum_scalar a c)); rewrite (ics_aux_ok (interp_vl v) c); rewrite H. rewrite (interp_m_ok a v). auto. Qed. Lemma canonical_sum_scalar2_ok : forall (l:varlist) (s:canonical_sum), Aequiv (interp_setcs (canonical_sum_scalar2 l s)) (Amult (interp_vl l) (interp_setcs s)). Proof. simple induction s; simpl in |- *; intros; auto. rewrite (monom_insert_ok a (varlist_merge l v) (canonical_sum_scalar2 l c)). rewrite (ics_aux_ok (interp_m a v) c). rewrite (interp_m_ok a v). rewrite H. rewrite (varlist_merge_ok l v). setoid_replace (Amult (interp_vl l) (Aplus (Amult a (interp_vl v)) (interp_setcs c))) with (Aplus (Amult (interp_vl l) (Amult a (interp_vl v))) (Amult (interp_vl l) (interp_setcs c))); [ idtac | trivial ]. auto. rewrite (varlist_insert_ok (varlist_merge l v) (canonical_sum_scalar2 l c)). rewrite (ics_aux_ok (interp_vl v) c). rewrite H. rewrite (varlist_merge_ok l v). auto. Qed. Lemma canonical_sum_scalar3_ok : forall (c:A) (l:varlist) (s:canonical_sum), Aequiv (interp_setcs (canonical_sum_scalar3 c l s)) (Amult c (Amult (interp_vl l) (interp_setcs s))). Proof. simple induction s; simpl in |- *; intros. rewrite (SSR_mult_zero_right S T (interp_vl l)). auto. rewrite (monom_insert_ok (Amult c a) (varlist_merge l v) (canonical_sum_scalar3 c l c0)). rewrite (ics_aux_ok (interp_m a v) c0). rewrite (interp_m_ok a v). rewrite H. rewrite (varlist_merge_ok l v). setoid_replace (Amult (interp_vl l) (Aplus (Amult a (interp_vl v)) (interp_setcs c0))) with (Aplus (Amult (interp_vl l) (Amult a (interp_vl v))) (Amult (interp_vl l) (interp_setcs c0))); [ idtac | trivial ]. setoid_replace (Amult c (Aplus (Amult (interp_vl l) (Amult a (interp_vl v))) (Amult (interp_vl l) (interp_setcs c0)))) with (Aplus (Amult c (Amult (interp_vl l) (Amult a (interp_vl v)))) (Amult c (Amult (interp_vl l) (interp_setcs c0)))); [ idtac | trivial ]. setoid_replace (Amult (Amult c a) (Amult (interp_vl l) (interp_vl v))) with (Amult c (Amult a (Amult (interp_vl l) (interp_vl v)))); [ idtac | trivial ]. auto. rewrite (monom_insert_ok c (varlist_merge l v) (canonical_sum_scalar3 c l c0)) . rewrite (ics_aux_ok (interp_vl v) c0). rewrite H. rewrite (varlist_merge_ok l v). setoid_replace (Aplus (Amult c (Amult (interp_vl l) (interp_vl v))) (Amult c (Amult (interp_vl l) (interp_setcs c0)))) with (Amult c (Aplus (Amult (interp_vl l) (interp_vl v)) (Amult (interp_vl l) (interp_setcs c0)))); [ idtac | trivial ]. auto. Qed. Lemma canonical_sum_prod_ok : forall x y:canonical_sum, Aequiv (interp_setcs (canonical_sum_prod x y)) (Amult (interp_setcs x) (interp_setcs y)). Proof. simple induction x; simpl in |- *; intros. trivial. rewrite (canonical_sum_merge_ok (canonical_sum_scalar3 a v y) (canonical_sum_prod c y)). rewrite (canonical_sum_scalar3_ok a v y). rewrite (ics_aux_ok (interp_m a v) c). rewrite (interp_m_ok a v). rewrite (H y). setoid_replace (Amult a (Amult (interp_vl v) (interp_setcs y))) with (Amult (Amult a (interp_vl v)) (interp_setcs y)); [ idtac | trivial ]. setoid_replace (Amult (Aplus (Amult a (interp_vl v)) (interp_setcs c)) (interp_setcs y)) with (Aplus (Amult (Amult a (interp_vl v)) (interp_setcs y)) (Amult (interp_setcs c) (interp_setcs y))); [ idtac | trivial ]. trivial. rewrite (canonical_sum_merge_ok (canonical_sum_scalar2 v y) (canonical_sum_prod c y)) . rewrite (canonical_sum_scalar2_ok v y). rewrite (ics_aux_ok (interp_vl v) c). rewrite (H y). trivial. Qed. Theorem setspolynomial_normalize_ok : forall p:setspolynomial, Aequiv (interp_setcs (setspolynomial_normalize p)) (interp_setsp p). Proof. simple induction p; simpl in |- *; intros; trivial. rewrite (canonical_sum_merge_ok (setspolynomial_normalize s) (setspolynomial_normalize s0)). rewrite H; rewrite H0; trivial. rewrite (canonical_sum_prod_ok (setspolynomial_normalize s) (setspolynomial_normalize s0)). rewrite H; rewrite H0; trivial. Qed. Lemma canonical_sum_simplify_ok : forall s:canonical_sum, Aequiv (interp_setcs (canonical_sum_simplify s)) (interp_setcs s). Proof. simple induction s; simpl in |- *; intros. trivial. generalize (SSR_eq_prop T a Azero). elim (Aeq a Azero). simpl in |- *. intros. rewrite (ics_aux_ok (interp_m a v) c). rewrite (interp_m_ok a v). rewrite (H0 I). setoid_replace (Amult Azero (interp_vl v)) with Azero; [ idtac | trivial ]. rewrite H. trivial. intros; simpl in |- *. generalize (SSR_eq_prop T a Aone). elim (Aeq a Aone). intros. rewrite (ics_aux_ok (interp_m a v) c). rewrite (interp_m_ok a v). rewrite (H1 I). simpl in |- *. rewrite (ics_aux_ok (interp_vl v) (canonical_sum_simplify c)). rewrite H. auto. simpl in |- *. intros. rewrite (ics_aux_ok (interp_m a v) (canonical_sum_simplify c)). rewrite (ics_aux_ok (interp_m a v) c). rewrite H; trivial. rewrite (ics_aux_ok (interp_vl v) (canonical_sum_simplify c)). rewrite H. auto. Qed. Theorem setspolynomial_simplify_ok : forall p:setspolynomial, Aequiv (interp_setcs (setspolynomial_simplify p)) (interp_setsp p). Proof. intro. unfold setspolynomial_simplify in |- *. rewrite (canonical_sum_simplify_ok (setspolynomial_normalize p)). exact (setspolynomial_normalize_ok p). Qed. End semi_setoid_rings. Arguments Cons_varlist : default implicits. Arguments Cons_monom : default implicits. Arguments SetSPconst : default implicits. Arguments SetSPplus : default implicits. Arguments SetSPmult : default implicits. Section setoid_rings. Set Implicit Arguments. Variable vm : varmap A. Variable T : Setoid_Ring_Theory Aequiv Aplus Amult Aone Azero Aopp Aeq. Hint Resolve (STh_plus_comm T). Hint Resolve (STh_plus_assoc T). Hint Resolve (STh_plus_assoc2 S T). Hint Resolve (STh_mult_comm T). Hint Resolve (STh_mult_assoc T). Hint Resolve (STh_mult_assoc2 S T). Hint Resolve (STh_plus_zero_left T). Hint Resolve (STh_plus_zero_left2 S T). Hint Resolve (STh_mult_one_left T). Hint Resolve (STh_mult_one_left2 S T). Hint Resolve (STh_mult_zero_left S plus_morph mult_morph T). Hint Resolve (STh_mult_zero_left2 S plus_morph mult_morph T). Hint Resolve (STh_distr_left T). Hint Resolve (STh_distr_left2 S T). Hint Resolve (STh_plus_reg_left S plus_morph T). Hint Resolve (STh_plus_permute S plus_morph T). Hint Resolve (STh_mult_permute S mult_morph T). Hint Resolve (STh_distr_right S plus_morph T). Hint Resolve (STh_distr_right2 S plus_morph T). Hint Resolve (STh_mult_zero_right S plus_morph mult_morph T). Hint Resolve (STh_mult_zero_right2 S plus_morph mult_morph T). Hint Resolve (STh_plus_zero_right S T). Hint Resolve (STh_plus_zero_right2 S T). Hint Resolve (STh_mult_one_right S T). Hint Resolve (STh_mult_one_right2 S T). Hint Resolve (STh_plus_reg_right S plus_morph T). Hint Resolve refl_equal sym_equal trans_equal. (*Hints Resolve refl_eqT sym_eqT trans_eqT.*) Hint Immediate T. (*** Definitions *) Inductive setpolynomial : Type := | SetPvar : index -> setpolynomial | SetPconst : A -> setpolynomial | SetPplus : setpolynomial -> setpolynomial -> setpolynomial | SetPmult : setpolynomial -> setpolynomial -> setpolynomial | SetPopp : setpolynomial -> setpolynomial. Fixpoint setpolynomial_normalize (x:setpolynomial) : canonical_sum := match x with | SetPplus l r => canonical_sum_merge (setpolynomial_normalize l) (setpolynomial_normalize r) | SetPmult l r => canonical_sum_prod (setpolynomial_normalize l) (setpolynomial_normalize r) | SetPconst c => Cons_monom c Nil_var Nil_monom | SetPvar i => Cons_varlist (Cons_var i Nil_var) Nil_monom | SetPopp p => canonical_sum_scalar3 (Aopp Aone) Nil_var (setpolynomial_normalize p) end. Definition setpolynomial_simplify (x:setpolynomial) := canonical_sum_simplify (setpolynomial_normalize x). Fixpoint setspolynomial_of (x:setpolynomial) : setspolynomial := match x with | SetPplus l r => SetSPplus (setspolynomial_of l) (setspolynomial_of r) | SetPmult l r => SetSPmult (setspolynomial_of l) (setspolynomial_of r) | SetPconst c => SetSPconst c | SetPvar i => SetSPvar i | SetPopp p => SetSPmult (SetSPconst (Aopp Aone)) (setspolynomial_of p) end. (*** Interpretation *) Fixpoint interp_setp (p:setpolynomial) : A := match p with | SetPconst c => c | SetPvar i => varmap_find Azero i vm | SetPplus p1 p2 => Aplus (interp_setp p1) (interp_setp p2) | SetPmult p1 p2 => Amult (interp_setp p1) (interp_setp p2) | SetPopp p1 => Aopp (interp_setp p1) end. (*** Properties *) Unset Implicit Arguments. Lemma setspolynomial_of_ok : forall p:setpolynomial, Aequiv (interp_setp p) (interp_setsp vm (setspolynomial_of p)). simple induction p; trivial; simpl in |- *; intros. rewrite H; rewrite H0; trivial. rewrite H; rewrite H0; trivial. rewrite H. rewrite (STh_opp_mult_left2 S plus_morph mult_morph T Aone (interp_setsp vm (setspolynomial_of s))). rewrite (STh_mult_one_left T (interp_setsp vm (setspolynomial_of s))). trivial. Qed. Theorem setpolynomial_normalize_ok : forall p:setpolynomial, setpolynomial_normalize p = setspolynomial_normalize (setspolynomial_of p). simple induction p; trivial; simpl in |- *; intros. rewrite H; rewrite H0; reflexivity. rewrite H; rewrite H0; reflexivity. rewrite H; simpl in |- *. elim (canonical_sum_scalar3 (Aopp Aone) Nil_var (setspolynomial_normalize (setspolynomial_of s))); [ reflexivity | simpl in |- *; intros; rewrite H0; reflexivity | simpl in |- *; intros; rewrite H0; reflexivity ]. Qed. Theorem setpolynomial_simplify_ok : forall p:setpolynomial, Aequiv (interp_setcs vm (setpolynomial_simplify p)) (interp_setp p). intro. unfold setpolynomial_simplify in |- *. rewrite (setspolynomial_of_ok p). rewrite setpolynomial_normalize_ok. rewrite (canonical_sum_simplify_ok vm (Semi_Setoid_Ring_Theory_of A Aequiv S Aplus Amult Aone Azero Aopp Aeq plus_morph mult_morph T) (setspolynomial_normalize (setspolynomial_of p))) . rewrite (setspolynomial_normalize_ok vm (Semi_Setoid_Ring_Theory_of A Aequiv S Aplus Amult Aone Azero Aopp Aeq plus_morph mult_morph T) (setspolynomial_of p)) . trivial. Qed. End setoid_rings. End setoid.