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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 *)
(************************************************************************)
(* *)
(* Micromega: A reflexive tactic using the Positivstellensatz *)
(* *)
(* Frédéric Besson (Irisa/Inria) 2006-2008 *)
(* *)
(************************************************************************)
Require Import OrderedRing.
Require Import RingMicromega.
Require Import Refl.
Require Import QArith.
Require Import Qfield.
(*Declare ML Module "micromega_plugin".*)
Lemma Qsor : SOR 0 1 Qplus Qmult Qminus Qopp Qeq Qle Qlt.
Proof.
constructor; intros ; subst ; try (intuition (subst; auto with qarith)).
apply Q_Setoid.
rewrite H ; rewrite H0 ; reflexivity.
rewrite H ; rewrite H0 ; reflexivity.
rewrite H ; auto ; reflexivity.
rewrite <- H ; rewrite <- H0 ; auto.
rewrite H ; rewrite H0 ; auto.
rewrite <- H ; rewrite <- H0 ; auto.
rewrite H ; rewrite H0 ; auto.
apply Qsrt.
eapply Qle_trans ; eauto.
apply (Qlt_not_eq n m H H0) ; auto.
destruct(Q_dec n m) as [[H1 |H1] | H1 ] ; tauto.
apply (Qplus_le_compat p p n m (Qle_refl p) H).
generalize (Qmult_lt_compat_r 0 n m H0 H).
rewrite Qmult_0_l.
auto.
compute in H.
discriminate.
Qed.
Lemma QSORaddon :
SORaddon 0 1 Qplus Qmult Qminus Qopp Qeq Qle (* ring elements *)
0 1 Qplus Qmult Qminus Qopp (* coefficients *)
Qeq_bool Qle_bool
(fun x => x) (fun x => x) (pow_N 1 Qmult).
Proof.
constructor.
constructor ; intros ; try reflexivity.
apply Qeq_bool_eq; auto.
constructor.
reflexivity.
intros x y.
apply Qeq_bool_neq ; auto.
apply Qle_bool_imp_le.
Qed.
(*Definition Zeval_expr := eval_pexpr 0 Zplus Zmult Zminus Zopp (fun x => x) (fun x => Z_of_N x) (Zpower).*)
Require Import EnvRing.
Fixpoint Qeval_expr (env: PolEnv Q) (e: PExpr Q) : Q :=
match e with
| PEc c => c
| PEX j => env j
| PEadd pe1 pe2 => (Qeval_expr env pe1) + (Qeval_expr env pe2)
| PEsub pe1 pe2 => (Qeval_expr env pe1) - (Qeval_expr env pe2)
| PEmul pe1 pe2 => (Qeval_expr env pe1) * (Qeval_expr env pe2)
| PEopp pe1 => - (Qeval_expr env pe1)
| PEpow pe1 n => Qpower (Qeval_expr env pe1) (Z_of_N n)
end.
Lemma Qeval_expr_simpl : forall env e,
Qeval_expr env e =
match e with
| PEc c => c
| PEX j => env j
| PEadd pe1 pe2 => (Qeval_expr env pe1) + (Qeval_expr env pe2)
| PEsub pe1 pe2 => (Qeval_expr env pe1) - (Qeval_expr env pe2)
| PEmul pe1 pe2 => (Qeval_expr env pe1) * (Qeval_expr env pe2)
| PEopp pe1 => - (Qeval_expr env pe1)
| PEpow pe1 n => Qpower (Qeval_expr env pe1) (Z_of_N n)
end.
Proof.
destruct e ; reflexivity.
Qed.
Definition Qeval_expr' := eval_pexpr Qplus Qmult Qminus Qopp (fun x => x) (fun x => x) (pow_N 1 Qmult).
Lemma QNpower : forall r n, r ^ Z_of_N n = pow_N 1 Qmult r n.
Proof.
destruct n ; reflexivity.
Qed.
Lemma Qeval_expr_compat : forall env e, Qeval_expr env e = Qeval_expr' env e.
Proof.
induction e ; simpl ; subst ; try congruence.
reflexivity.
rewrite IHe.
apply QNpower.
Qed.
Definition Qeval_op2 (o : Op2) : Q -> Q -> Prop :=
match o with
| OpEq => Qeq
| OpNEq => fun x y => ~ x == y
| OpLe => Qle
| OpGe => fun x y => Qle y x
| OpLt => Qlt
| OpGt => fun x y => Qlt y x
end.
Definition Qeval_formula (e:PolEnv Q) (ff : Formula Q) :=
let (lhs,o,rhs) := ff in Qeval_op2 o (Qeval_expr e lhs) (Qeval_expr e rhs).
Definition Qeval_formula' :=
eval_formula Qplus Qmult Qminus Qopp Qeq Qle Qlt (fun x => x) (fun x => x) (pow_N 1 Qmult).
Lemma Qeval_formula_compat : forall env f, Qeval_formula env f <-> Qeval_formula' env f.
Proof.
intros.
unfold Qeval_formula.
destruct f.
repeat rewrite Qeval_expr_compat.
unfold Qeval_formula'.
unfold Qeval_expr'.
split ; destruct Fop ; simpl; auto.
Qed.
Definition Qeval_nformula :=
eval_nformula 0 Qplus Qmult Qeq Qle Qlt (fun x => x) .
Definition Qeval_op1 (o : Op1) : Q -> Prop :=
match o with
| Equal => fun x : Q => x == 0
| NonEqual => fun x : Q => ~ x == 0
| Strict => fun x : Q => 0 < x
| NonStrict => fun x : Q => 0 <= x
end.
Lemma Qeval_nformula_dec : forall env d, (Qeval_nformula env d) \/ ~ (Qeval_nformula env d).
Proof.
exact (fun env d =>eval_nformula_dec Qsor (fun x => x) env d).
Qed.
Definition QWitness := Psatz Q.
Definition QWeakChecker := check_normalised_formulas 0 1 Qplus Qmult Qeq_bool Qle_bool.
Require Import List.
Lemma QWeakChecker_sound : forall (l : list (NFormula Q)) (cm : QWitness),
QWeakChecker l cm = true ->
forall env, make_impl (Qeval_nformula env) l False.
Proof.
intros l cm H.
intro.
unfold Qeval_nformula.
apply (checker_nf_sound Qsor QSORaddon l cm).
unfold QWeakChecker in H.
exact H.
Qed.
Require Import Tauto.
Definition Qnormalise := @cnf_normalise Q 0 1 Qplus Qmult Qminus Qopp Qeq_bool.
Definition Qnegate := @cnf_negate Q 0 1 Qplus Qmult Qminus Qopp Qeq_bool.
Definition QTautoChecker (f : BFormula (Formula Q)) (w: list QWitness) : bool :=
@tauto_checker (Formula Q) (NFormula Q)
Qnormalise
Qnegate QWitness QWeakChecker f w.
Lemma QTautoChecker_sound : forall f w, QTautoChecker f w = true -> forall env, eval_f (Qeval_formula env) f.
Proof.
intros f w.
unfold QTautoChecker.
apply (tauto_checker_sound Qeval_formula Qeval_nformula).
apply Qeval_nformula_dec.
intros. rewrite Qeval_formula_compat. unfold Qeval_formula'. now apply (cnf_normalise_correct Qsor QSORaddon).
intros. rewrite Qeval_formula_compat. unfold Qeval_formula'. now apply (cnf_negate_correct Qsor QSORaddon).
intros t w0.
apply QWeakChecker_sound.
Qed.
(* Local Variables: *)
(* coding: utf-8 *)
(* End: *)
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