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fuzzy.v
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fuzzy.v
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From HB Require Import structures.
Require Import Coq.Program.Equality.
From mathcomp Require Import all_ssreflect all_algebra.
From mathcomp Require Import lra.
From mathcomp Require Import all_classical reals ereal signed topology derive.
From mathcomp Require Import normedtype sequences exp measure lebesgue_measure.
From mathcomp Require Import lebesgue_integral hoelder.
Require Import mathcomp_extra analysis_extra ldl.
(**md**************************************************************************)
(* # Properties of fuzzy DLs: *)
(* Lukaseiwicz, Yager, Godel and product *)
(* *)
(* grouped by DL, unless generic enough to apply to all fuzzy DLs *)
(* *)
(* *)
(* ## Soundness *)
(* - translations_Fun_coincide == shows that the Boolean translation *)
(* and the fuzzy translation coincide on expressions of type Fun_T *)
(* - translations_Vector_coincide == shows that the Boolean translation *)
(* and the fuzzy translation coincide on expressions of type Vector_T *)
(* - translations_Index_coincide == shows that the Boolean translation *)
(* and the fuzzy translation coincide on expressions of type Index_T *)
(* - translations_Real_coincide == shows that the Boolean translation and *)
(* - translate_Bool_T_01 == invariant for the translation: all values are in *)
(* the range $[-1, 0]$ *)
(* - nary_inversion_andE1 == inversion lemma for conjunction/true *)
(* - nary_inversion_andE0 == inversion lemma for conjuntion/false *)
(* - nary_inversion_orE1 == inversion lemma for disjunction/true *)
(* - nary_inversion_orE0 == inversion lemma for disjunction/false *)
(* the fuzzy translation coincide on expressions of type Real_T *)
(* - soundness == final soundness result for Godel and product *)
(* *)
(* ## Structural properties for Lukasiewicz *)
(* - Lukasiewicz_andC_nary == n-ary commutativity of conjunction *)
(* - Lukasiewicz_andC == commutativity of conjunction *)
(* - Lukasiewicz_orC_nary == n-ary commutativity of disjunction *)
(* - Lukasiewicz_orC_ == commutativity of disjunction *)
(* - Lukasiewicz_orA == associativity of disjunction *)
(* - Lukasiewicz_andA == associativity of conjunction *)
(* *)
(* ## Structural properties for Yager *)
(* - Yager_andC_nary == n-ary commutativity of conjunction *)
(* - Yager_andC == commutativity of conjunction *)
(* - Yager_orC_nary == n-ary commutativity of disjunction *)
(* - Yager_orC_ == commutativity of disjunction *)
(* - Yager_orA == associativity of disjunction *)
(* - Yager_andA == associativity of conjunction *)
(* *)
(* ## Structural properties for Godel *)
(* - Godel_andI == idempotence of conjunction *)
(* - Godel_orI == idempotence of disjunction *)
(* - Godel_andC_nary == n-ary commutativity of conjunction *)
(* - Godel_andC == commutativity of conjunction *)
(* - Godel_orC_nary == n-ary commutativity of disjunction *)
(* - Godel_orC_ == commutativity of disjunction *)
(* - Godel_orA == associativity of disjunction *)
(* - Godel_andA == associativity of conjunction *)
(* *)
(* ## Structural properties for product *)
(* - product_andC_nary == n-ary commutativity of conjunction *)
(* - product_andC == commutativity of conjunction *)
(* - product_orC_nary == n-ary commutativity of disjunction *)
(* - product_orC_ == commutativity of disjunction *)
(* - product_orA == associativity of disjunction *)
(* - product_andA == associativity of conjunction *)
(* *)
(* ## Shadow-lifting *)
(* - product_and v == $\product_{i < n} v_i$ *)
(* - shadowlifting_product_andE == shadow-lifting for product *)
(******************************************************************************)
Import Num.Def Num.Theory GRing.Theory.
Import Order.TTheory.
Import numFieldTopology.Exports.
Section translation_lemmas.
Local Open Scope ring_scope.
Local Open Scope ldl_scope.
Context {R : realType}.
Variables (l : DL) (p : R).
Hypothesis p1 : 1 <= p.
Local Notation "[[ e ]]_ l" := (@translation R l p _ e).
Lemma translations_Fun_coincide:
forall n m (e : expr (Fun_T n m)), [[ e ]]_l = [[ e ]]_B.
Proof.
dependent induction e => //=.
Qed.
Lemma translations_Vector_coincide: forall n (e : @expr R (Vector_T n)),
[[ e ]]_l = [[ e ]]_B.
Proof.
dependent induction e => //=.
dependent destruction e1.
by rewrite (IHe2 _ p1 _ e2 erefl JMeq_refl).
Qed.
Lemma translations_Index_coincide: forall n (e : expr (Index_T n)),
[[ e ]]_l = [[ e ]]_B.
Proof.
dependent induction e => //=.
Qed.
Lemma translations_Real_coincide (e : expr Real_T):
[[ e ]]_l = [[ e ]]_B.
Proof.
dependent induction e => //=;
rewrite ?(IHe1 e1 erefl JMeq_refl) ?(IHe2 e2 erefl JMeq_refl) ?(IHe e erefl JMeq_refl) //=.
by rewrite translations_Vector_coincide translations_Index_coincide.
Qed.
Lemma translate_Bool_T_01 dl (e : expr Bool_T_def) :
0 <= [[ e ]]_ dl <= 1.
Proof.
dependent induction e using expr_ind'.
- rewrite /=; case b; lra.
- move: H. case: dl; rewrite /=; move=> /List.Forall_forall H.
+ rewrite /sumR/maxr. case: ifP.
* by lra.
* move=> /negbT; rewrite -leNgt => -> /=.
rewrite big_map -lerBrDr subrr subr_le0 sum_01// => e el0.
by rewrite (andP (H e _ _ _ _)).2 //; exact/In_in.
+ rewrite /sumR/maxr. case: ifP.
* by lra.
* move=> /negbT; rewrite -leNgt => -> /=.
by rewrite big_map gerBl ?powR_ge0.
+ apply/andP; split.
* rewrite /minR big_seq.
rewrite le_bigmin// => i /mapP[x xl0 ->].
by apply: (andP (@H _ _ _ _ _)).1 => //; rewrite -In_in.
* rewrite /minR big_map big_seq.
rewrite bigmin_idl.
suff : forall (x y : R), minr x y <= x => // x y.
by rewrite /minr; case: ifPn; lra.
+ rewrite /prodR.
apply: prod01 => e.
move/mapP => [x xl0 ->].
by apply: H _ _ _ _ _ => //; rewrite -In_in.
- move: H. case: dl; rewrite /=; move=> /List.Forall_forall H.
+ rewrite /sumR/minr. case: ifP.
* move=> /ltW ->.
rewrite andbT big_map big_seq sumr_ge0// => e.
by move=> /In_in/H /(_ e erefl) /(_ _)/andP[|].
* by lra.
+ rewrite /sumR/minr. case: ifP.
* move=> /ltW ->.
by rewrite andbT big_map big_seq powR_ge0.
* by lra.
+ rewrite /maxR big_map big_seq.
apply/andP; split.
* rewrite bigmax_idl.
suff : forall (x y : R), x <= maxr x y => // x y.
by rewrite /maxr; case: ifPn; lra.
* rewrite bigmax_le ?ler01// => i il0.
by apply: (andP (H _ _ _ _ _)).2 => //; rewrite -In_in.
+ rewrite /product_dl_prod big_map product_dl_mul_seq_01=> //i il0.
by apply: H => //; rewrite -In_in.
- move: IHe => /(_ e erefl JMeq_refl).
case dl => //=; set a := [[e]]_ _; lra.
- case: c => /=; case: ifP => ?.
- by case: ([[e1]]_dl <= [[e2]]_dl)%R; rewrite lexx ler01.
- by rewrite le_maxr lexx orbT/= le_maxl ler01 gerBl// le_maxr lexx orbT.
- by case: ([[e1]]_dl == [[e2]]_dl); rewrite lexx ler01.
- by rewrite le_maxr lexx orbT/= le_maxl ler01 gerBl// normr_ge0 andTb.
Qed.
Lemma nary_inversion_andE1 (s : seq (expr (Bool_T_def))) :
[[ ldl_and s ]]_ l = 1 ->
forall i, (i < size s)%N -> [[ nth (ldl_bool _ false) s i ]]_ l = 1.
Proof.
have := translate_Bool_T_01 l.
case: l => /= H.
- move/eqP. rewrite maxr01 /sumR eq_sym -subr_eq subrr eq_sym subr_eq0.
move/eqP; rewrite big_map psumr_eqsize.
+ move => h i iEs.
move: h => /(_ (nth (ldl_bool _ false) s i)).
apply.
apply/(nthP (ldl_bool _ false)).
by exists i.
+ move => i //=.
by move: (H i); set a := [[i]]_ _; lra.
- move/eqP.
rewrite maxr01 eq_sym addrC -subr_eq subrr eq_sym oppr_eq0 powR_eq0 invr_eq0 => /andP [+ _].
+ rewrite /sumR big_map psumr_eq0.
move => /allP h i iEs.
apply/eqP.
move: h => /(_ (nth (ldl_bool _ false) s i)).
rewrite implyTb powR_eq0 subr_eq0 eq_sym (gt_eqF (lt_le_trans _ p1))// ?andbT.
apply.
by apply/(nthP (ldl_bool _ false)); exists i.
+ by move=> ? //= _; exact: powR_ge0.
- move/eqP.
rewrite /minR big_map => /bigmin_eqP/= h i iEs.
apply/eqP.
rewrite eq_sym eq_le.
rewrite ((andP (H _)).2) h //.
exact: mem_nth.
- move/eqP. rewrite /prodR big_map.
move => h i si.
apply (@prod1_01 _ (map (@translation R product p (Bool_T _)) s)) => // [e||].
- by move=> /mapP[x _ ->].
- by apply/eqP; rewrite big_map.
- by apply/mapP; eexists; last reflexivity; exact: mem_nth.
Qed.
Lemma nary_inversion_andE0 (s : seq (expr (Bool_T_def))) :
l <> Lukasiewicz -> l <> Yager -> [[ ldl_and s ]]_ l = 0 ->
exists2 i, ([[ nth (ldl_bool _ false) s i ]]_ l == 0) & (i < size s)%N.
Proof.
have H := translate_Bool_T_01. move: H.
have p0 := lt_le_trans ltr01 p1.
case: l => //=; move => H.
- move => l1 l2; move/eqP.
rewrite /minR big_map.
elim: s.
+ by rewrite big_nil oner_eq0.
+ move=> a l0 IH.
rewrite big_cons {1}/minr.
case: ifPn => [_ ?|_]; first by exists 0%N => //; rewrite ltn0Sn andbT.
by move/IH => [i i0]; exists i.+1.
- move=> l1 l2 /eqP.
rewrite /prodR big_map prodf_seq_eq0 => /hasP[e eEs/= /eqP e0].
move/(nthP (ldl_bool _ false)) : eEs => [i iEs ie].
by exists i => //; rewrite ie e0 eqxx.
Qed.
Lemma nary_inversion_orE1 (Es : seq (expr (Bool_T_def))) :
l <> Lukasiewicz -> l <> Yager -> [[ ldl_or Es ]]_ l = 1 ->
exists2 i, ([[ nth (ldl_bool _ false) Es i ]]_ l == 1) & (i < size Es)%N.
Proof.
have H := translate_Bool_T_01 l. move: H.
have p0 := lt_le_trans ltr01 p1.
case: l => //=; move => H.
- move => l1 l2; move/eqP.
rewrite /maxR big_map big_seq.
elim: Es.
+ by rewrite big_nil eq_sym oner_eq0.
+ move=> a l0 IH.
rewrite -big_seq big_cons {1}/maxr.
case: ifPn => [_|_ a1]; last by exists 0%N => //; rewrite a1 ltn0Sn.
rewrite big_seq; move/IH => [i i1].
by exists i.+1.
- move => l1 l2 /eqP.
rewrite /product_dl_prod big_map big_seq.
elim: Es.
+ by rewrite big_nil eq_sym oner_eq0.
+ move=> a l0 IH.
rewrite -big_seq big_cons {1}/product_dl_mul.
move/product_dl_mul_inv => [|||/eqP].
* exact: H.
* by apply: product_dl_mul_seq_01.
* by exists 0%N => //; rewrite a0 eqxx.
* by rewrite big_seq; move/IH => [x ?]; exists x.+1.
Qed.
Lemma nary_inversion_orE0 (Es : seq (expr (Bool_T_def))) :
[[ ldl_or Es ]]_ l = 0 ->
forall i, (i < size Es)%N -> [[ nth (ldl_bool _ false) Es i ]]_ l = 0.
Proof.
have H := translate_Bool_T_01 l. move: H.
have p0 := lt_le_trans ltr01 p1.
case: l => //=; move => H.
- move/eqP. rewrite minr10 /sumR.
rewrite big_map.
rewrite (@bigsum_0x R _ _ Es) => h i.
by move=> iEs; apply: h; rewrite mem_nth.
exact: (andP (translate_Bool_T_01 _ _)).1.
- move/eqP; rewrite minr10 /sumR powR_eq0.
move/andP => [].
rewrite (@gt_eqF _ _ (p^-1)) ?invr_gt0//.
rewrite big_seq big_map psumr_eq0=>[|i]; last by rewrite powR_ge0.
move/allP => h _ i iEs.
apply/eqP.
suff: ([[nth (ldl_bool _ false) Es i]]_Yager == 0) && (p != 0).
by move/andP=>[].
rewrite -powR_eq0.
apply: (implyP (h (nth (ldl_bool _ false) Es i) _)).
by rewrite mem_nth.
apply/mapP; exists (nth (ldl_bool _ false) Es i) => //.
by rewrite mem_nth.
- rewrite /maxR/product_dl_prod.
elim: Es => [h i|a l0 IH h]; first by rewrite nth_nil.
elim => /=[_|].
+ move: h.
rewrite big_cons big_map {1}/maxr.
case: ifPn => // /[swap] ->.
have := H a; set b := [[_]]_ _; lra.
+ move=> n h' nl0.
apply: IH => //.
move: h; rewrite !big_map big_cons {1}/maxr.
case: ifPn => // /[swap] ->; rewrite -leNgt => bigle0.
by apply/eqP; rewrite eq_le bigle0 bigmax_idl le_maxr lexx.
- rewrite /product_dl_prod big_map.
elim: Es => // a l0 IH.
rewrite big_cons => /eqP /product_dl_prod_inv0 h.
case => /=[_|i].
+ apply: (h _ _).1 => //.
exact: product_dl_mul_seq_01.
+ rewrite ltnS => isize.
apply: IH =>//.
apply: (h _ _).2 => //.
exact: product_dl_mul_seq_01.
Qed.
Lemma soundness (e : expr (Bool_T_def)) b :
l <> Lukasiewicz -> l <> Yager ->
[[ e ]]_ l = [[ ldl_bool _ b ]]_ l -> [[ e ]]_B = b.
Proof.
dependent induction e using expr_ind' => ll ly.
- move: b b0 => [] [] //=; lra.
- rewrite List.Forall_forall in H.
rewrite [ [[ldl_bool _ b]]_l ]/=.
move: b => [].
+ move/nary_inversion_andE1.
rewrite /= big_map big_seq big_all_cond => h.
apply: allT => x/=.
apply/implyP => /nthP xnth.
have [i il0 <-] := xnth (ldl_bool _ false).
by apply: H => //; rewrite ?h// -In_in mem_nth.
+ move/nary_inversion_andE0.
rewrite /= big_map big_all.
elim=>// i /eqP i0 isize.
apply/allPn; exists (nth (ldl_bool _ false) l0 i); first by rewrite mem_nth.
apply/negPf; apply: H => //.
by rewrite -In_in mem_nth.
- rewrite List.Forall_forall in H.
rewrite [ [[ldl_bool _ b]]_l]/=.
move: b => [].
+ move/nary_inversion_orE1.
rewrite /= big_map big_has.
elim=>// i /eqP i0 isize.
apply/hasP; exists (nth (ldl_bool _ false) l0 i); first by rewrite mem_nth.
apply: H => //.
by rewrite -In_in mem_nth.
+ move/nary_inversion_orE0.
rewrite /= big_map big_has => h.
apply/hasPn => x.
move/nthP => xnth.
have [i il0 <-] := xnth (ldl_bool _ false).
by apply/negPf; apply: H => //; rewrite ?h// -In_in mem_nth.
- move=>/=h; rewrite (IHe e erefl JMeq_refl (~~ b) ll ly) ?negbK//.
move: h; case: b => /=; lra.
- case: c; rewrite //=; rewrite -!translations_Real_coincide;
set t1 := _ e1; set t2 := _ e2.
+ case: ifPn => [/eqP ->|e12eq].
have [] := leP (-t2) t2 => /=; case: b; lra.
rewrite /maxr.
have ? : 0 < `|t1 + t2| by rewrite normr_gt0 addr_eq0.
have ? : 0 < `|t1 + t2|^-1 by rewrite invr_gt0.
case: b; repeat case: ifPn; [lra|lra| | |lra| |lra|]; rewrite -?leNgt.
* by rewrite pmulr_llt0; lra.
* rewrite pmulr_lge0// subr_ge0 => t120 _ ?.
have : (t1 - t2) / `|t1 + t2| = 0 by lra.
nra.
* rewrite pmulr_lge0// subr_ge0 => t120.
rewrite subr_lt0.
rewrite ltr_pdivlMr ?normr_gt0 ?addr_eq0// mul1r.
rewrite lter_norml opprD opprK.
lra.
* rewrite pmulr_lge0// => t120.
rewrite subr_ge0 ler_pdivrMr ?normr_gt0 ?addr_eq0// mul1r.
rewrite lter_normr => ? ?.
have : (t1 - t2) / `|t1 + t2| = 1 by lra.
move/divr1_eq => /eqP.
by rewrite eq_sym eqr_norml; lra.
+ case: ifP => [/eqP ->|e12eq].
have [] := eqVneq (- t2) t2 => /=; case: b; lra.
rewrite /maxr.
case: b; case: ifPn; first by lra; rewrite -?leNgt.
* move=> _ H.
have : `|(t1 - t2) / (t1 + t2)| == 0.
clear -H.
simpl in *.
lra.
simpl in *.
rewrite normr_eq0 mulf_eq0 invr_eq0.
clear -H e12eq.
lra.
* rewrite subr_lt0 lter_normr.
have [|t120] := leP (t1+t2) 0.
rewrite le_eqVlt => /orP [|t120]; first lra.
rewrite -mulNr !ltr_ndivlMr// !mul1r opprD opprK.
lra.
rewrite -mulNr.
rewrite !ltr_pdivlMr// !mul1r opprD opprK.
lra.
* move=> H0 H1.
have : `|(t1 - t2) / (t1 + t2)| == 1.
simpl in *.
clear -e12eq H0 H1.
lra.
rewrite eqr_norml.
nra.
Qed.
End translation_lemmas.
Definition product_and {R : fieldType} {n} (u : 'rV[R]_n) : R :=
\prod_(i < n) u ``_ i.
Section shadow_lifting_product_and.
Context {R : realType}.
Local Open Scope ring_scope.
Local Open Scope classical_set_scope.
Variable M : nat.
Hypothesis M0 : M != 0%N.
Lemma shadowlifting_product_andE p : p > 0 ->
forall i, ('d (@product_and R M.+1) '/d i) (const_mx p) = p ^+ M.
Proof.
move=> p0 i.
rewrite /partial.
have /cvg_lim : h^-1 * (product_and (const_mx p + h *: err_vec i) -
@product_and _ M.+1 (const_mx p))
@[h --> (0:R)^'] --> p ^+ M.
rewrite /product_and.
have H (h : R) : h != 0 ->
\prod_(x < M.+1) (const_mx p + h *: err_vec i) 0 x -
\prod_(x < M.+1) const_mx (m:=M.+1) p 0 x = h * p ^+ M.
move=> h0; rewrite [X in X - _](bigD1 i)//= !mxE eqxx mulr1.
rewrite (eq_bigr (fun=> p)); last first.
by move=> j ji; rewrite !mxE eq_sym (negbTE ji) mulr0 addr0.
rewrite [X in _ - X](eq_bigr (fun=> p)); last by move=> *; rewrite mxE.
rewrite [X in _ - X](bigD1 i)//= -mulrBl addrAC subrr add0r; congr (h * _).
transitivity (\prod_(i0 in @predC1 [the eqType of 'I_M.+1] i) p).
by apply: eq_bigl => j; rewrite inE.
rewrite prodr_const; congr (_ ^+ _).
by rewrite cardC1 card_ord.
have : h^-1 * (h * p ^+ M) @[h --> (0:R)^'] --> p ^+ M.
have : {near (0:R)^', (fun=> p ^+ M) =1 (fun h => h^-1 * (h * p ^+ M))}.
near=> h; rewrite mulrA mulVf ?mul1r//.
by near: h; exact: nbhs_dnbhs_neq.
by move/near_eq_cvg/cvg_trans; apply; exact: cvg_cst.
apply: cvg_trans; apply: near_eq_cvg; near=> k.
have <-// := H k.
congr (_ * (_ - _)).
apply: eq_bigr => /= j _.
by rewrite !mxE.
by near: k; exact: nbhs_dnbhs_neq.
by apply; exact: Rhausdorff.
Unshelve. all: by end_near. Qed.
Corollary shadow_lifting_product_and : shadow_lifting (@product_and R M.+1).
Proof. by move=> p p0 i; rewrite shadowlifting_product_andE// exprn_gt0. Qed.
End shadow_lifting_product_and.
Section Lukasiewicz_lemmas.
Local Open Scope ldl_scope.
Local Open Scope ring_scope.
Context {R : realType}.
Variable p : R.
Local Notation "[[ e ]]_ l" := (translation l p e).
Lemma Lukasiewicz_andC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_and s1]]_Lukasiewicz = [[ldl_and s2]]_Lukasiewicz.
Proof.
by move=> pi; rewrite /=/sumR !big_map (perm_big _ pi)/= (perm_size pi).
Qed.
Lemma Lukasiewicz_andC (e1 e2 : expr Bool_T_def) :
[[ e1 `/\ e2 ]]_Lukasiewicz = [[ e2 `/\ e1 ]]_Lukasiewicz.
Proof.
rewrite /=/sumR ?big_cons ?big_nil.
by rewrite addr0 addr0 (addrC (_ e1)).
Qed.
Lemma Lukasiewicz_orC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_or s1]]_Lukasiewicz = [[ldl_or s2]]_Lukasiewicz.
Proof.
by move=> pi; rewrite /=/sumR !big_map (perm_big _ pi)/=.
Qed.
Lemma Lukasiewicz_orC (e1 e2 : expr Bool_T_def) :
[[ e1 `\/ e2 ]]_Lukasiewicz = [[ e2 `\/ e1 ]]_Lukasiewicz.
Proof.
rewrite /=/sumR/maxR ?big_cons ?big_nil.
by rewrite /= addr0 addr0 (addrC (_ e1)).
Qed.
Lemma Lukasiewicz_orA (e1 e2 e3 : expr Bool_T_def) :
[[ (e1 `\/ (e2 `\/ e3)) ]]_Lukasiewicz = [[ ((e1 `\/ e2) `\/ e3) ]]_Lukasiewicz.
Proof.
have := translate_Bool_T_01 p Lukasiewicz e1.
have := translate_Bool_T_01 p Lukasiewicz e2.
have := translate_Bool_T_01 p Lukasiewicz e3.
rewrite /=/sumR/minR?big_cons ?big_nil.
rewrite /minr.
repeat case: ifP; set a := [[_]]__; set b := [[_]]__; set c := [[_]]__; lra.
Qed.
Theorem Lukasiewicz_andA (e1 e2 e3 : expr Bool_T_def) : (0 < p)%R ->
[[ (e1 `/\ e2) `/\ e3]]_Lukasiewicz = [[ e1 `/\ (e2 `/\ e3) ]]_Lukasiewicz.
Proof.
have := translate_Bool_T_01 p Lukasiewicz e1.
have := translate_Bool_T_01 p Lukasiewicz e2.
have := translate_Bool_T_01 p Lukasiewicz e3.
rewrite /=/sumR/maxR/minR/product_dl_prod ?big_cons ?big_nil.
set t1 := _ e1.
set t2 := _ e2.
set t3 := _ e3.
rewrite /maxr.
by repeat case: ifP; lra.
Qed.
End Lukasiewicz_lemmas.
Section Yager_lemmas.
Local Open Scope ldl_scope.
Local Open Scope ring_scope.
Context {R : realType}.
Variable p : R.
Hypothesis p1 : 1 <= p.
Local Notation "[[ e ]]_ l" := (translation l p e).
Lemma Yager_andC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_and s1]]_Yager = [[ldl_and s2]]_Yager.
Proof.
by move=> pi; rewrite /=/sumR !big_map (perm_big _ pi)/=.
Qed.
Lemma Yager_andC (e1 e2 : expr Bool_T_def) :
[[ e1 `/\ e2 ]]_Yager = [[ e2 `/\ e1 ]]_Yager.
Proof.
rewrite /=/sumR ?big_cons ?big_nil.
by rewrite /= addr0 addr0 (addrC (_ `^ _)).
Qed.
Lemma Yager_orC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_or s1]]_Yager = [[ldl_or s2]]_Yager.
Proof.
by move=> pi; rewrite /=/sumR !big_map (perm_big _ pi)/=.
Qed.
Lemma Yager_orC (e1 e2 : expr Bool_T_def) :
[[ e1 `\/ e2 ]]_Yager = [[ e2 `\/ e1 ]]_Yager.
Proof.
rewrite /=/sumR/maxR ?big_cons ?big_nil.
by rewrite /= addr0 addr0 (addrC (_ `^ _)).
Qed.
Lemma Yager_orA (e1 e2 e3 : expr Bool_T_def) :
[[ (e1 `\/ (e2 `\/ e3)) ]]_Yager = [[ ((e1 `\/ e2) `\/ e3) ]]_Yager.
Proof.
have p0 : 0 < p by rewrite (lt_le_trans ltr01).
have ? : p != 0 by exact: lt0r_neq0.
have := translate_Bool_T_01 p Yager e1.
have := translate_Bool_T_01 p Yager e2.
have := translate_Bool_T_01 p Yager e3.
rewrite /=/sumR/maxR/minR/product_dl_prod ?big_cons ?big_nil.
rewrite ![in _ + _]addr0 addr0 addr0.
set t1 := _ e1.
set t2 := _ e2.
set t3 := _ e3.
have powRpinv : 1 = 1 `^ p^-1.
by rewrite powR1.
have powRge1 : forall x, 0 <= x -> 1 <= x `^ p^-1 -> 1 <= x.
move=> x x0; rewrite {1}powRpinv.
move/(@ge0_ler_powR _ p (ltW p0)).
by rewrite -!powRrM !mulVf// powR1 powRr1//; apply; rewrite nnegrE ?powR_ge0.
move => ht3 ht2 ht1.
rewrite {2}/minr.
case: ifPn => [h1|].
- rewrite -powRrM mulVf ?p0 ?powRr1 ?addr_ge0 ?powR_ge0// addrA.
rewrite {3}/minr.
case: ifPn => [h2|].
by rewrite -powRrM mulVf ?p0 ?powRr1 ?powR_ge0// addr_ge0 ?powR_ge0.
rewrite -leNgt; move/(powRge1 _ (addr_ge0 (powR_ge0 _ _) (powR_ge0 _ _))) => h2.
rewrite {2}/minr.
case: ifPn.
suff : (1 `^ p + t3 `^ p) `^ p^-1 >= 1.
set a := (1 `^ p + t3 `^ p) `^ p^-1; lra.
by rewrite {1}(_: 1 = 1`^p^-1) ?ge0_ler_powR ?powR1 ?invr_ge0 ?(ltW p0) ?nnegrE ?addr_ge0 ?powR_ge0// cprD powR_ge0.
rewrite -leNgt /minr=> h3.
case: ifPn => //.
suff : (t1 `^ p + t2 `^ p + t3 `^ p) `^ p^-1 >= 1.
set a := (t1 `^ p + t2 `^ p + t3 `^ p) `^ p^-1; lra.
rewrite powRpinv ge0_ler_powR ?invr_ge0 ?nnegrE ?(ltW p0) ?addr_ge0 ?powR_ge0//.
apply: le_trans; first exact: h2.
by rewrite lerDl powR_ge0.
- rewrite -leNgt {1}/minr.
move/(powRge1 _ (addr_ge0 (powR_ge0 _ _) (powR_ge0 _ _))) => h1.
case: ifPn => [|_].
suff : (t1 `^ p + 1 `^ p) `^ p^-1 >= 1.
set a := (t1 `^ p + 1 `^ p) `^ p^-1; lra.
by rewrite {1}powRpinv ge0_ler_powR ?invr_ge0 ?(ltW p0) ?nnegrE ?addr_ge0 ?powR_ge0 ?powR1// lerDr powR_ge0.
rewrite {2}/minr.
case: ifPn => [h2|_].
rewrite -powRrM mulVf// powRr1 ?addr_ge0 ?powR_ge0//.
rewrite /minr.
case: ifPn => //.
suff : (t1 `^ p + t2 `^ p + t3 `^ p) `^ p^-1 >= 1.
set a := (t1 `^ p + t2 `^ p + t3 `^ p) `^ p^-1; lra.
rewrite {1}powRpinv ge0_ler_powR ?invr_ge0 ?(ltW p0) ?nnegrE ?addr_ge0 ?powR_ge0//.
apply: le_trans; first exact: h1.
by rewrite -addrA lerDr powR_ge0.
rewrite /minr.
case: ifPn => //.
suff : (1 `^ p + t3 `^ p) `^ p^-1 >= 1.
set a := (1 `^ p + t3 `^ p) `^ p^-1; lra.
rewrite {1}powRpinv ge0_ler_powR ?invr_ge0 ?(ltW p0) ?nnegrE ?addr_ge0 ?powR_ge0//.
by rewrite powR1 lerDl powR_ge0.
Qed.
Theorem Yager_andA (e1 e2 e3 : expr Bool_T_def) : (0 < p) ->
[[ (e1 `/\ e2) `/\ e3]]_Yager = [[ e1 `/\ (e2 `/\ e3) ]]_Yager.
Proof.
move=> p0.
have pneq0 : p != 0 by exact: lt0r_neq0.
have := translate_Bool_T_01 p Yager e1.
have := translate_Bool_T_01 p Yager e2.
have := translate_Bool_T_01 p Yager e3.
rewrite /=/sumR/maxR/minR/product_dl_prod ?big_cons ?big_nil.
set t1 := _ e1.
set t2 := _ e2.
set t3 := _ e3.
set a1 := (1 - t1)`^p.
set a2 := (1 - t2)`^p.
set a3 := (1 - t3)`^p.
have a1ge0 : 0 <= a1 by rewrite powR_ge0.
have a2ge0 : 0 <= a2 by rewrite powR_ge0.
have a3ge0 : 0 <= a3 by rewrite powR_ge0.
have powRpinv : 1 = 1 `^ p^-1.
by rewrite powR1.
have powRle1 : forall x, 0 <= x -> x `^ p^-1 <= 1 -> x <= 1.
move=> x x0; rewrite {1}powRpinv.
move/(@ge0_ler_powR _ p (ltW p0)).
by rewrite -!powRrM !mulVf// powR1 powRr1//; apply; rewrite nnegrE ?powR_ge0.
have powRgt1 : forall x, 0 <= x -> 1 < x `^ p^-1 -> 1 < x.
move=> x x0; rewrite {1}powRpinv.
move/(@gt0_ltr_powR _ p p0).
by rewrite -!powRrM !mulVf// powR1 powRr1// !nnegrE; apply => //; exact: powR_ge0.
have se_ge0 r := @addr_ge0 R _ _ (@powR_ge0 _ _ r) (@powR_ge0 _ _ r).
rewrite {2}/maxr=> ht3 ht2 ht1.
case: ifPn; rewrite addr0 subr_lt0.
- move/(powRgt1 _ (addr_ge0 a1ge0 a2ge0)) => h1.
rewrite subr0 powR1 addr0.
rewrite {3}/maxr; case: ifPn; rewrite addr0.
+ rewrite subr0 subr_lt0 => h2.
rewrite {1}/maxr; case: ifPn.
* rewrite subr_lt0 => h3.
rewrite /maxr; case: ifPn => //.
rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 (powR_ge0 _ _) (powR_ge0 _ _))).
rewrite powR1 gerDr -/a1 => h4.
have -> : a1 = 0 by lra.
by rewrite add0r powR1 subrr.
* rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 ler01 (powR_ge0 _ _))).
rewrite gerDl -/a3 => h3.
have -> : a3 = 0 by lra.
rewrite addr0 powR1 subrr.
rewrite /maxr; case: ifPn => //.
rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 (powR_ge0 _ _) ler01)).
rewrite -/a1 gerDr => h5.
have -> : a1 = 0 by lra.
by rewrite add0r powR1 subrr.
+ rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 (powR_ge0 _ _) (powR_ge0 _ _))).
rewrite -/a2 -/a3 => h2.
rewrite {1}/maxr; case: ifPn.
* rewrite subr_lt0.
move/(powRgt1 _ (addr_ge0 ler01 a3ge0)).
rewrite cprD => h3.
rewrite opprD opprK addrA subrr add0r -powRrM mulVf// powRr1 ?addr_ge0// addrA.
rewrite /maxr; case: ifPn => //.
rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 (addr_ge0 a1ge0 a2ge0) a3ge0)).
lra.
* rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 ler01 a3ge0)).
rewrite cprD => h3.
have -> : a3 = 0 by lra.
rewrite !addr0 powR1 subrr.
rewrite /maxr; case: ifPn => //.
rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 a1ge0 (powR_ge0 _ _))).
rewrite opprB addrCA subrr addr0 -powRrM mulVf// powRr1//.
lra.
- rewrite -leNgt.
move/(powRle1 _ (addr_ge0 a1ge0 a2ge0)) => h1.
rewrite {3}/maxr; case: ifPn.
+ rewrite !addr0 !subr0 subr_lt0.
move/(powRgt1 _ (addr_ge0 a2ge0 a3ge0)) => h2.
rewrite {2}/maxr; case: ifPn.
* rewrite subr_lt0 powR1.
move/(powRgt1 _ (addr_ge0 a1ge0 ler01)).
rewrite cprD => h3.
rewrite /maxr; case: ifPn => //.
rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 (powR_ge0 _ _) a3ge0)).
rewrite opprB addrCA subrr addr0 -powRrM mulVf// powRr1 ?addr_ge0//.
lra.
* rewrite -leNgt subr_ge0 powR1.
move/(powRle1 _ (addr_ge0 a1ge0 ler01)).
rewrite gerDr => h3.
move: h1.
have -> : a1 = 0 by lra.
rewrite add0r => h1.
rewrite add0r powR1 subrr.
rewrite /maxr; case: ifPn => //.
rewrite -leNgt subr_ge0.
move/(powRle1 _ (addr_ge0 (powR_ge0 _ _) a3ge0)).
rewrite opprB addrCA subrr addr0 -powRrM mulVf// powRr1//.
lra.
+ rewrite -leNgt subr_ge0 addr0.
move/(powRle1 _ (addr_ge0 a2ge0 a3ge0)) => h2.
rewrite {1}opprB (@addrC _ _ (_ - _)) -addrA (@addrC _ (-1)) subrr addr0.
rewrite -powRrM mulVf// powRr1 ?addr_ge0// addr0.
rewrite {1}opprB (@addrC _ _ (_ - _)).
rewrite -[in RHS]addrA (@addrC _ (-1)) subrr addr0.
by rewrite -powRrM mulVf ?pneq0 ?powRr1 ?addrA ?addr_ge0.
Qed.
End Yager_lemmas.
Section Godel_lemmas.
Local Open Scope ldl_scope.
Local Open Scope ring_scope.
Context {R : realType}.
Variable p : R.
Local Notation "[[ e ]]_ l" := (translation l p e).
Lemma Godel_andI (e : expr Bool_T_def) : [[ e `/\ e ]]_Godel = [[ e ]]_Godel.
Proof.
rewrite /=/minR ?big_cons ?big_nil.
have := translate_Bool_T_01 p Godel e.
set t1 := _ e.
move => h.
rewrite /=/minr; repeat case: ifP; lra.
Qed.
Lemma Godel_orI (e : expr Bool_T_def) : [[ e `\/ e ]]_Godel = [[ e ]]_Godel.
Proof.
rewrite /= /maxR !big_cons big_nil.
have /max_idPl -> : 0 <= [[ e ]]_Godel.
by have /andP[] := translate_Bool_T_01 p Godel e.
by rewrite maxxx.
Qed.
Lemma Godel_andC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_and s1]]_Godel = [[ldl_and s2]]_Godel.
Proof.
by move=> pi; rewrite /=/minR !big_map (perm_big _ pi)/=.
Qed.
Lemma Godel_andC (e1 e2 : expr Bool_T_def) :
[[ e1 `/\ e2 ]]_Godel = [[ e2 `/\ e1 ]]_Godel.
Proof.
rewrite /=/minR ?big_cons ?big_nil.
by rewrite /=/minr; repeat case: ifP; lra.
Qed.
Lemma Godel_orC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_or s1]]_Godel = [[ldl_or s2]]_Godel.
Proof.
by move=> pi; rewrite /=/maxR !big_map (perm_big _ pi)/=.
Qed.
Lemma Godel_orC (e1 e2 : expr Bool_T_def) :
[[ e1 `\/ e2 ]]_Godel = [[ e2 `\/ e1 ]]_Godel.
Proof.
rewrite /=/sumR/maxR ?big_cons ?big_nil.
rewrite /=/maxr; repeat case: ifP; lra.
Qed.
Lemma Godel_orA (e1 e2 e3 : expr Bool_T_def) :
[[ (e1 `\/ (e2 `\/ e3)) ]]_Godel = [[ ((e1 `\/ e2) `\/ e3) ]]_Godel.
Proof.
rewrite /=/sumR/maxR ?big_cons ?big_nil.
rewrite /maxr.
by repeat case: ifPn => //; lra.
Qed.
Theorem Godel_andA (e1 e2 e3 : expr Bool_T_def) : (0 < p) ->
[[ (e1 `/\ e2) `/\ e3]]_Godel = [[ e1 `/\ (e2 `/\ e3) ]]_Godel.
Proof.
rewrite /=/sumR/minR !big_cons !big_nil.
have := translate_Bool_T_01 p Godel e1.
have := translate_Bool_T_01 p Godel e2.
have := translate_Bool_T_01 p Godel e3.
set t1 := _ e1.
set t2 := _ e2.
set t3 := _ e3.
move => h1 h2 h3 p0.
rewrite /minr.
by repeat case: ifPn => //; lra.
Qed.
End Godel_lemmas.
Section product_lemmas.
Local Open Scope ldl_scope.
Local Open Scope ring_scope.
Context {R : realType}.
Variable p : R.
Local Notation "[[ e ]]_ l" := (translation l p e).
Lemma product_andC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_and s1]]_Godel = [[ldl_and s2]]_Godel.
Proof.
by move=> pi; rewrite /=/minR !big_map (perm_big _ pi)/=.
Qed.
Lemma product_andC (e1 e2 : expr Bool_T_def) :
[[ e1 `/\ e2 ]]_product = [[ e2 `/\ e1 ]]_product.
Proof.
rewrite /=/prodR ?big_cons ?big_nil.
by rewrite /= mulr1 mulr1 mulrC.
Qed.
Lemma product_orC_nary (s1 s2 : seq (expr Bool_T_def)) :
perm_eq s1 s2 -> [[ldl_or s1]]_Godel = [[ldl_or s2]]_Godel.
Proof.
by move=> pi; rewrite /=/maxR !big_map (perm_big _ pi)/=.
Qed.
Lemma product_orC (e1 e2 : expr Bool_T_def) :
[[ e1 `\/ e2 ]]_product = [[ e2 `\/ e1 ]]_product.
Proof.
rewrite /=/sumR/maxR/product_dl_prod ?big_cons ?big_nil.
by rewrite /=/product_dl_mul addr0 addr0 mulr0 mulr0 subr0 subr0 mulrC -(addrC (_ e2)).
Qed.
Lemma product_orA (e1 e2 e3 : expr Bool_T_def) :
[[ (e1 `\/ (e2 `\/ e3)) ]]_product = [[ ((e1 `\/ e2) `\/ e3) ]]_product.
Proof.
rewrite /=/sumR/product_dl_prod ?big_cons ?big_nil.
rewrite /product_dl_mul !addr0 !mulr0 !subr0.
lra.
Qed.
Theorem product_andA (e1 e2 e3 : expr Bool_T_def) : 0 < p ->
[[ (e1 `/\ e2) `/\ e3]]_product = [[ e1 `/\ (e2 `/\ e3) ]]_product.
Proof.
rewrite /=/sumR/maxR/minR/product_dl_prod ?big_cons ?big_nil.
set t1 := _ e1.
set t2 := _ e2.
set t3 := _ e3.
rewrite /prodR/= !big_cons !big_nil.
lra.
Qed.
End product_lemmas.