Top

Module mathcomp.analysis.forms

From HB Require Import structures.
From mathcomp Require Import all_ssreflect ssralg fingroup zmodp poly ssrnum.
From mathcomp Require Import matrix mxalgebra vector falgebra ssrnum fieldext.
From mathcomp Require Import vector mathcomp_extra.


Set Implicit Arguments.
Unset Strict Implicit.
Unset Printing Implicit Defensive.

Local Open Scope ring_scope.
Import GRing.Theory Num.Theory.

Reserved Notation "'[ u , v ]"
  (at level 2, format "'[hv' ''[' u , '/ ' v ] ']'").
Reserved Notation "'[ u , v ]_ M"
         (at level 2, format "'[hv' ''[' u , '/ ' v ]_ M ']'").
Reserved Notation "'[ u ]_ M" (at level 2, format "''[' u ]_ M").
Reserved Notation "'[ u ]" (at level 2, format "''[' u ]").
Reserved Notation "u '``_' i"
    (at level 3, i at level 2, format "u '``_' i").
Reserved Notation "A ^_|_" (at level 8, format "A ^_|_").
Reserved Notation "A _|_ B" (at level 69, format "A _|_ B").
Reserved Notation "eps_theta .-sesqui" (at level 2, format "eps_theta .-sesqui").

Notation "u '``_' i" := (u (0 : 'I_1) i) : ring_scope.
Notation "''e_' i" := (delta_mx 0 i)
 (format "''e_' i", at level 3) : ring_scope.

Local Notation "M ^ phi" := (map_mx phi M).
Local Notation "M ^t phi" := (map_mx phi (M ^T)) (phi at level 30, at level 30).

Lemma eq_map_mx_id (R : ringType) m n (M : 'M[R]_(m,n)) (f : R -> R) :
  f =1 id -> M ^ f = M.

Proof.

by move=> /eq_map_mx->; rewrite map_mx_id. Qed.

HB.mixin Record isBilinear (R : ringType) (U U' : lmodType R) (V : zmodType)
    (s : R -> V -> V) (s' : R -> V -> V) (f : U -> U' -> V) := {
  additivel_subproof : forall u', additive (f^~ u');
  additiver_subproof : forall u, additive (f u);
  linearl_subproof : forall u', scalable_for s (f^~ u');
  linearr_subproof : forall u, scalable_for s' (f u);
}.

HB.structure Definition Bilinear (R : ringType) (U U' : lmodType R) (V : zmodType)
    (s : R -> V -> V) (s' : R -> V -> V) :=
  {f of isBilinear R U U' V s s' f}.

Definition bilinear_for (R : ringType) (U U' : lmodType R) (V : zmodType)
    (s : GRing.Scale.law R V) (s' : GRing.Scale.law R V) (f : U -> U' -> V) :=
  ((forall u', GRing.linear_for (s : R -> V -> V) (f^~ u'))
  * (forall u, GRing.linear_for s' (f u)))%type.

HB.factory Record bilinear_isBilinear (R : ringType) (U U' : lmodType R) (V : zmodType)
    (s : GRing.Scale.law R V) (s' : GRing.Scale.law R V) (f : U -> U' -> V) := {
  bilinear_subproof : bilinear_for s s' f;
}.

HB.builders Context R U U' V s s' f of bilinear_isBilinear R U U' V s s' f.
HB.instance Definition _ := isBilinear.Build R U U' V s s' f
    (fun u' => additive_linear (bilinear_subproof.1 u'))
    (fun u => additive_linear (bilinear_subproof.2 u))
    (fun u' => scalable_linear (bilinear_subproof.1 u'))
    (fun u => scalable_linear (bilinear_subproof.2 u)).
HB.end.

Module BilinearExports.
Notation bilinear f := (bilinear_for *:%R *:%R f).
Notation biscalar f := (bilinear_for *%R *%R f).
Module Bilinear.
Definition map (R : ringType) (U U' : lmodType R) (V : zmodType)
    (s : R -> V -> V) (s' : R -> V -> V)
    (phUU'V : phant (U -> U' -> V)) := Bilinear.type U U' s s'.
End Bilinear.
Notation "{ 'bilinear' fUV | s & s' }" := (Bilinear.map s s' (Phant fUV))
  (at level 0, format "{ 'bilinear' fUV | s & s' }") : ring_scope.
Notation "{ 'bilinear' fUV | s }" := (Bilinear.map s.1 s.2 (Phant fUV))
  (at level 0, format "{ 'bilinear' fUV | s }") : ring_scope.
Notation "{ 'bilinear' fUV }" := {bilinear fUV | *:%R & *:%R}
  (at level 0, format "{ 'bilinear' fUV }") : ring_scope.
Notation "{ 'biscalar' U }" := {bilinear U -> U -> _ | *%R & *%R}
  (at level 0, format "{ 'biscalar' U }") : ring_scope.
Notation "[ 'bilinear' 'of' f 'as' g ]" := (Bilinear.clone _ _ _ _ _ _ f g)
  (at level 0, format "[ 'bilinear' 'of' f 'as' g ]") : form_scope.
Notation "[ 'bilinear' 'of' f ]" := (Bilinear.clone _ _ _ _ _ _ f _)
  (at level 0, format "[ 'bilinear' 'of' f ]") : form_scope.
End BilinearExports.
Export BilinearExports.

Section applyr.

Variables (R : ringType) (U U' : lmodType R) (V : zmodType) (s s' : R -> V -> V).

Definition applyr_head t (f : U -> U' -> V) u v := let: tt := t in f v u.

End applyr.

Notation applyr := (applyr_head tt).

Section BilinearTheory.

Variable R : ringType.

Section GenericProperties.

Variables (U U' : lmodType R) (V : zmodType) (s : R -> V -> V) (s' : R -> V -> V).
Variable f : {bilinear U -> U' -> V | s & s'}.

Section GenericPropertiesr.

Variable z : U.

#[local, non_forgetful_inheritance]
HB.instance Definition _ :=
  GRing.isAdditive.Build _ _ (f z) (@additiver_subproof _ _ _ _ _ _ f z).
#[local, non_forgetful_inheritance]
HB.instance Definition _ :=
  GRing.isScalable.Build _ _ _ _ (f z) (@linearr_subproof _ _ _ _ _ _ f z).

Lemma linear0r : f z 0 = 0. Proof. by rewrite raddf0.Lemma linearNr : {morph f z : x / - x}. Proof. exact: raddfN.Lemma linearDr : {morph f z : x y / x + y}. Proof. exact: raddfD.Lemma linearBr : {morph f z : x y / x - y}. Proof. exact: raddfB.Lemma linearMnr n : {morph f z : x / x *+ n}. Proof. exact: raddfMn.Lemma linearMNnr n : {morph f z : x / x *- n}. Proof. exact: raddfMNn.Lemma linear_sumr I r (P : pred I) E :
  f z (\sum_(i <- r | P i) E i) = \sum_(i <- r | P i) f z (E i).

Proof.

exact: raddf_sum. Qed.

Lemma linearZr_LR : scalable_for s' (f z)

Proof.

exact: linearZ_LR. Qed.

Lemma linearPr a : {morph f z : u v / a *: u + v >-> s' a u + v}.

Proof.

exact: linearP. Qed.

End GenericPropertiesr.

Lemma applyrE x : applyr f x =1 f^~ x. Proof. by [].
Section GenericPropertiesl.

Variable z : U'.

#[local, non_forgetful_inheritance]
HB.instance Definition _ :=
  GRing.isAdditive.Build _ _ (applyr f z) (@additivel_subproof _ _ _ _ _ _ f z).
#[local, non_forgetful_inheritance]
HB.instance Definition _ :=
  GRing.isScalable.Build _ _ _ _ (applyr f z) (@linearl_subproof _ _ _ _ _ _ f z).

Lemma linear0l : f 0 z = 0. Proof. by rewrite -applyrE raddf0.Lemma linearNl : {morph f^~ z : x / - x}.

Proof.

by move=> ?; rewrite -applyrE raddfN. Qed.

Lemma linearDl : {morph f^~ z : x y / x + y}.

Proof.

by move=> ??; rewrite -applyrE raddfD. Qed.

Lemma linearBl : {morph f^~ z : x y / x - y}.

Proof.

by move=> ??; rewrite -applyrE raddfB. Qed.

Lemma linearMnl n : {morph f^~ z : x / x *+ n}.

Proof.

by move=> ?; rewrite -applyrE raddfMn. Qed.

Lemma linearMNnl n : {morph f^~ z : x / x *- n}.

Proof.

by move=> ?; rewrite -applyrE raddfMNn. Qed.

Lemma linear_suml I r (P : pred I) E :
  f (\sum_(i <- r | P i) E i) z = \sum_(i <- r | P i) f (E i) z.

Proof.

by rewrite -applyrE raddf_sum. Qed.

Lemma linearZl_LR : scalable_for s (f^~ z).

Proof.

by move=> ??; rewrite -applyrE linearZ_LR. Qed.

Lemma linearPl a : {morph f^~ z : u v / a *: u + v >-> s a u + v}.

Proof.

by move=> ??; rewrite -applyrE linearP. Qed.

End GenericPropertiesl.

End GenericProperties.

Section BidirectionalLinearZ.

Variables (U : lmodType R) (V : zmodType) (s : R -> V -> V).
Variables (S : ringType) (h : GRing.Scale.law S V).


End BidirectionalLinearZ.

End BilinearTheory.

Lemma mulmx_is_bilinear (R : comRingType) m n p :
  bilinear_for
    (GRing.Scale.Law.clone _ _ *:%R _) (GRing.Scale.Law.clone _ _ *:%R _)
    (@mulmx R m n p).

Proof.

split=> [u'|u] a x y /=.
- by rewrite mulmxDl scalemxAl.
- by rewrite mulmxDr scalemxAr.
Qed.

HB.instance Definition _ (R : comRingType) m n p :=
  bilinear_isBilinear.Build R
    [the lmodType R of 'M[R]_(m, n)] [the lmodType R of 'M[R]_(n, p)]
    [the zmodType of 'M[R]_(m, p)] _ _ (@mulmx R m n p)
    (mulmx_is_bilinear R m n p).





Section BilinearForms.

Variables (R : fieldType) (theta : {rmorphism R -> R}).
Variables (n : nat) (M : 'M[R]_n).
Implicit Types (a b : R) (u v : 'rV[R]_n) (N P Q : 'M[R]_n).

Definition form u v := (u *m M *m (v ^t theta)) 0 0.

Local Notation "''[' u , v ]" := (form u%R v%R) : ring_scope.
Local Notation "''[' u ]" := '[u, u] : ring_scope.

Lemma form0l u : '[0, u] = 0.

Proof.

by rewrite /form !mul0mx mxE. Qed.

Lemma form0r u : '[u, 0] = 0.

Proof.

by rewrite /form trmx0 map_mx0 mulmx0 mxE. Qed.

Lemma formDl u v w : '[u + v, w] = '[u, w] + '[v, w].

Proof.

by rewrite /form !mulmxDl mxE. Qed.

Lemma formDr u v w : '[u, v + w] = '[u, v] + '[u, w].

Proof.

by rewrite /form linearD !map_mxD !mulmxDr mxE. Qed.

Lemma formZr a u v : '[u, a *: v] = theta a * '[u, v].

Proof.

by rewrite /form !(linearZ, map_mxZ) /= mxE. Qed.

Lemma formZl a u v : '[a *: u, v] = a * '[u, v].

Proof.

by do !rewrite /form -[_ *: _ *m _]/(mulmxr _ _) linearZ /=; rewrite mxE.
Qed.

Lemma formNl u v : '[- u, v] = - '[u, v].

Proof.

by rewrite -scaleN1r formZl mulN1r. Qed.

Lemma formNr u v : '[u, - v] = - '[u, v].

Proof.

by rewrite -scaleN1r formZr rmorphN1 mulN1r. Qed.

Lemma formee i j : '['e_i, 'e_j] = M i j.

Proof.

rewrite /form -rowE -map_trmx map_delta_mx -[M in LHS]trmxK.
by rewrite -tr_col -trmx_mul -rowE !mxE.
Qed.

Lemma form0_eq0 : M = 0 -> forall u v, '[u, v] = 0.

Proof.

by rewrite/form=> -> u v; rewrite mulmx0 mul0mx mxE. Qed.

End BilinearForms.

Section Sesquilinear.

Variable R : fieldType.
Variable n : nat.
Implicit Types (a b : R) (u v : 'rV[R]_n) (N P Q : 'M[R]_n).

Section Def.
Variable eps_theta : (bool * {rmorphism R -> R}).

Definition sesqui :=
  [qualify M : 'M_n | M == ((-1) ^+ eps_theta.1) *: M ^t eps_theta.2].
Fact sesqui_key : pred_key sesqui. Proof. by [].Canonical sesqui_keyed := KeyedQualifier sesqui_key.
End Def.

Local Notation "eps_theta .-sesqui" := (sesqui eps_theta).

Variables (eps : bool) (theta : {rmorphism R -> R}).
Variables (M : 'M[R]_n).
Local Notation "''[' u , v ]" := (form theta M u%R v%R) : ring_scope.
Local Notation "''[' u ]" := '[u, u] : ring_scope.

Lemma sesquiE : (M \is (eps,theta).-sesqui) = (M == (-1) ^+ eps *: M ^t theta).

Proof.

by rewrite qualifE. Qed.

Lemma sesquiP : reflect (M = (-1) ^+ eps *: M ^t theta)
                        (M \is (eps,theta).-sesqui).

Proof.

by rewrite sesquiE; apply/eqP. Qed.

Hypothesis (thetaK : involutive theta).
Hypothesis (M_sesqui : M \is (eps, theta).-sesqui).

Lemma trmx_sesqui : M^T = (-1) ^+ eps *: M ^ theta.

Proof.

rewrite [in LHS](sesquiP _) // -mul_scalar_mx trmx_mul.
by rewrite tr_scalar_mx mul_mx_scalar map_trmx trmxK.
Qed.

Lemma maptrmx_sesqui : M^t theta = (-1) ^+ eps *: M.

Proof.

by rewrite trmx_sesqui map_mxZ rmorph_sign -map_mx_comp eq_map_mx_id.
Qed.

Lemma formC u v : '[u, v] = (-1) ^+ eps * theta '[v, u].

Proof.

rewrite /form [M in LHS](sesquiP _) // -mulmxA !mxE rmorph_sum mulr_sumr.
apply: eq_bigr => /= i _; rewrite !(mxE, mulr_sumr, mulr_suml, rmorph_sum).
apply: eq_bigr => /= j _; rewrite !mxE !rmorphM mulrCA -!mulrA.
by congr (_ * _); rewrite mulrA mulrC /= thetaK.
Qed.

Lemma form_eq0C u v : ('[u, v] == 0) = ('[v, u] == 0).

Proof.

by rewrite formC mulf_eq0 signr_eq0 /= fmorph_eq0. Qed.

Definition ortho m (B : 'M_(m,n)) := (kermx (M *m (B ^t theta))).
Local Notation "B ^_|_" := (ortho B) : ring_scope.
Local Notation "A _|_ B" := (A%MS <= B^_|_)%MS : ring_scope.

Lemma normalE u v : (u _|_ v) = ('[u, v] == 0).

Proof.

by rewrite (sameP sub_kermxP eqP) mulmxA [_ *m _^t _]mx11_scalar fmorph_eq0.
Qed.

Lemma form_eq0P {u v} : reflect ('[u, v] = 0) (u _|_ v).

Proof.

by rewrite normalE; apply/eqP. Qed.

Lemma normalP p q (A : 'M_(p, n)) (B :'M_(q, n)) :
  reflect (forall (u v : 'rV_n), (u <= A)%MS -> (v <= B)%MS -> u _|_ v)
          (A _|_ B).

Proof.

apply: (iffP idP) => AnB.
  move=> u v uA vB; rewrite (submx_trans uA) // (submx_trans AnB) //.
  apply/sub_kermxP; have /submxP [w ->] := vB.
  rewrite trmx_mul map_mxM !mulmxA -[kermx _ *m _ *m _]mulmxA.
  by rewrite [kermx _ *m _](sub_kermxP _) // mul0mx.
apply/rV_subP => u /AnB /(_ _) /sub_kermxP uMv; apply/sub_kermxP.
suff: forall m (v : 'rV[R]_m),
  (forall i, v *m 'e_i ^t theta = 0 :> 'M_1) -> v = 0.
  apply => i; rewrite !mulmxA -!mulmxA -map_mxM -trmx_mul uMv //.
  by apply/submxP; exists 'e_i.
move=> /= m v Hv; apply: (can_inj (@trmxK _ _ _)).
rewrite trmx0; apply/row_matrixP=> i; rewrite row0 rowE.
apply: (can_inj (@trmxK _ _ _)); rewrite trmx0 trmx_mul trmxK.
by rewrite -(map_delta_mx theta) map_trmx Hv.
Qed.

Lemma normalC p q (A : 'M_(p, n)) (B :'M_(q, n)) : (A _|_ B) = (B _|_ A).

Proof.

gen have nC : p q A B / A _|_ B -> B _|_ A; last by apply/idP/idP; apply/nC.
move=> AnB; apply/normalP => u v ? ?; rewrite normalE.
rewrite formC mulf_eq0 ?fmorph_eq0 ?signr_eq0 /=.
by rewrite -normalE (normalP _ _ AnB).
Qed.

Lemma normal_ortho_mx p (A : 'M_(p, n)) : ((A^_|_) _|_ A).

Proof.

by []. Qed.

Lemma normal_mx_ortho p (A : 'M_(p, n)) : (A _|_ (A^_|_)).

Proof.

by rewrite normalC. Qed.

Lemma rank_normal u : (\rank (u ^_|_) >= n.-1)%N.

Proof.

rewrite mxrank_ker -subn1 leq_sub2l //.
by rewrite (leq_trans (mxrankM_maxr _ _)) // rank_leq_col.
Qed.

Definition rad := 1%:M^_|_.

Lemma rad_ker : rad = kermx M.

Proof.

by rewrite /rad /ortho trmx1 map_mx1 mulmx1. Qed.

Theorem formDd u v : u _|_ v -> '[u + v] = '[u] + '[v].

Proof.

move=> uNv; rewrite formDl !formDr ['[v, u]]formC.
by rewrite ['[u, v]](form_eq0P _) // rmorph0 mulr0 addr0 add0r.
Qed.

Lemma formZ a u : '[a *: u]= (a * theta a) * '[u].

Proof.

by rewrite formZl formZr mulrA. Qed.

Lemma formN u : '[- u] = '[u].

Proof.

by rewrite formNr formNl opprK. Qed.

Lemma form_sign m u : '[(-1) ^+ m *: u] = '[u].

Proof.

by rewrite -signr_odd scaler_sign; case: odd; rewrite ?formN. Qed.

Lemma formD u v : let d := '[u, v] in
  '[u + v] = '[u] + '[v] + (d + (-1) ^+ eps * theta d).

Proof.

by rewrite formDl !formDr ['[v, _]]formC [_ + '[v]]addrC addrACA. Qed.

Lemma formB u v : let d := '[u, v] in
  '[u - v] = '[u] + '[v] - (d + (-1) ^+ eps * theta d).

Proof.

by rewrite formD formN !formNr rmorphN mulrN -opprD. Qed.

Lemma formBd u v : u _|_ v -> '[u - v] = '[u] + '[v].

Proof.

by move=> uTv; rewrite formDd ?formN // normalE formNr oppr_eq0 -normalE.
Qed.

End Sesquilinear.

Notation "eps_theta .-sesqui" := (sesqui _ eps_theta) : ring_scope.

Notation symmetric_form := (false, idfun).-sesqui.
Notation skew := (true, idfun).-sesqui.
Notation hermitian := (false, @Num.conj_op _).-sesqui.