(* mathcomp analysis (c) 2017 Inria and AIST. License: CeCILL-C. *) From mathcomp Require Import all_ssreflect ssralg ssrnum. Require Import boolp ereal reals mathcomp_extra. Require Import classical_sets signed functions topology normedtype. Require Import prodnormedzmodule. (******************************************************************************) (* BACHMANN-LANDAU NOTATIONS : BIG AND LITTLE O *) (******************************************************************************) (******************************************************************************) (* F is a filter, K is an absRingType and V W X Y Z are normed spaces over K *) (* alternatively, K can be equal to the reals R (from the standard library *) (* for now) *) (* This library is very asymmetric, in multiple respects: *) (* - most rewrite rules can only be rewritten from left to right. *) (* e.g. an equation 'o_F f = 'O_G g can be used only from LEFT TO RIGHT *) (* - conversely most small 'o_F f in your goal are very specific, *) (* only 'a_F f is mutable *) (* *) (* - most notations are either parse only or print only. *) (* Indeed all the 'O_F notations contain a function which is NOT displayed. *) (* This might be confusing as sometimes you might get 'O_F g = 'O_F g *) (* and not be able to solve by reflexivity. *) (* - In order to have a look at the hidden function, rewrite showo. *) (* - Do not use showo during a normal proof. *) (* - All theorems should be stated so that when an impossible reflexivity *) (* is encountered, it is of the form 'O_F g = 'O_F g so that you *) (* know you should use eqOE in order to generalize your 'O_F g *) (* to an arbitrary 'O_F g *) (* *) (* To prove that f is a bigO of g near F, you should go back to filter *) (* reasoning only as a last resort. To do so, use the view eqOP. Similarly, *) (* you can use eqaddOP to prove that f is equal to g plus a bigO of e near F *) (* using filter reasoning. *) (* *) (* Parsable notations: *) (* [bigO of f] == recovers the canonical structure of big-o of f *) (* expands to itself *) (* f =O_F h == f is a bigO of h near F, *) (* this is the preferred way for statements. *) (* expands to the equation (f = 'O_F h) *) (* rewrite from LEFT to RIGHT only *) (* f = g +O_F h == f is equal to g plus a bigO near F, *) (* this is the preferred way for statements. *) (* expands to the equation (f = g + 'O_F h) *) (* rewrite from LEFT to RIGHT only *) (* /!\ When you have to prove *) (* (f =O_F h) or (f = g +O_F h). *) (* you must (apply: eqOE) as soon as possible in a proof *) (* in order to turn it into 'a_O_F f with a shelved content *) (* /!\ under rare circumstances, a hint may do that for you *) (* [O_F h of f] == returns a function with a bigO canonical structure *) (* provably equal to f if f is indeed a bigO of h *) (* provably equal to 0 otherwise *) (* expands to ('O_F h) *) (* 'O_F == pattern to match a bigO with a specific F *) (* 'O == pattern to match a bigO with a generic F *) (* f x =O_(x \near F) e x == alternative way of stating f =O_F e (provably *) (* equal using the lemma eqOEx *) (* *) (* Printing only notations: *) (* {O_F f} == the type of functions that are a bigO of f near F *) (* 'a_O_F f == an existential bigO, must come from (apply: eqOE) *) (* 'O_F f == a generic bigO, with a function you should not rely on, *) (* but there is no way you can use eqOE on it. *) (* *) (* The former works exactly the same by with littleo instead of bigO. *) (* *) (* Asymptotic equivalence: *) (* f ~_ F g == function f is asymptotically equivalent to *) (* function g for filter F, i.e., f = g +o_ F g *) (* f ~~_ F g == f == g +o_ F g (i.e., as a boolean relation) *) (* --> asymptotic equivalence proved to be an equivalence relation *) (* *) (* Big-Omega and big-Theta notations on the model of bigO and littleo: *) (* {Omega_F f} == the type of functions that are a big Omega of f near F *) (* [bigOmega of f] == recovers the canonical structure of big-Omega of f *) (* [Omega_F e of f] == returns a function with a bigOmega canonical structure *) (* provably equal to f if f is indeed a bigOmega of e *) (* or e otherwise *) (* f \is 'Omega_F(e) == f : T -> V is a bigOmega of e : T -> W near F *) (* f =Omega_F h == f : T -> V is a bigOmega of h : T -> V near F *) (* --> lemmas: relation with big-O, transitivity, product of functions, etc. *) (* *) (* Similar notations available for big-Theta. *) (* --> lemmas: relations with big-O and big-Omega, reflexivity, symmetry, *) (* transitivity, product of functions, etc. *) (* *) (* WARNING: The piece of syntax "=O_(" is only valid in the syntax *) (* "=O_(x \near F)", not in the syntax "=O_(x : U)". *) (* *) (******************************************************************************) Set Implicit Arguments. Unset Strict Implicit. Unset Printing Implicit Defensive. Declare Scope R_scope. Import Order.TTheory GRing.Theory Num.Theory. Reserved Notation "{o_ F f }" (at level 0, F at level 0, format "{o_ F f }"). Reserved Notation "[littleo 'of' f 'for' fT ]" (at level 0, f at level 0, format "[littleo 'of' f 'for' fT ]"). Reserved Notation "[littleo 'of' f ]" (at level 0, f at level 0, format "[littleo 'of' f ]"). Reserved Notation "'o_ x" (at level 200, x at level 0, only parsing). Reserved Notation "'o" (at level 200, only parsing). (* Parsing *) Reserved Notation "[o_ x e 'of' f ]" (at level 0, x, e at level 0, only parsing). (*Printing*) Reserved Notation "[o '_' x e 'of' f ]" (at level 0, x, e at level 0, format "[o '_' x e 'of' f ]"). (* These notations are printing only in order to display 'o without looking at the contents, use showo to display *) Reserved Notation "''o_' x e " (at level 0, x, e at level 0, format "''o_' x e "). Reserved Notation "''a_o_' x e " (at level 0, x, e at level 0, format "''a_o_' x e "). Reserved Notation "''o' '_' x" (at level 0, x at level 0, format "''o' '_' x"). Reserved Notation "f = g '+o_' F h" (at level 70, no associativity, g at next level, F at level 0, h at next level, format "f = g '+o_' F h"). Reserved Notation "f '=o_' F h" (at level 70, no associativity, F at level 0, h at next level, format "f '=o_' F h"). Reserved Notation "f == g '+o_' F h" (at level 70, no associativity, g at next level, F at level 0, h at next level, format "f == g '+o_' F h"). Reserved Notation "f '==o_' F h" (at level 70, no associativity, F at level 0, h at next level, format "f '==o_' F h"). Reserved Notation "[o_( x \near F ) ex 'of' fx ]" (at level 0, x, ex at level 0, only parsing). (*Printing*) Reserved Notation "[o '_(' x \near F ')' ex 'of' fx ]" (at level 0, x, ex at level 0, format "[o '_(' x \near F ')' ex 'of' fx ]"). (* These notations are printing only in order to display 'o without looking at the contents, use showo to display *) Reserved Notation "''o_(' x \near F ')' ex" (at level 0, x, ex at level 0, format "''o_(' x \near F ')' ex"). Reserved Notation "''a_o_(' x \near F ')' ex" (at level 0, x, ex at level 0, format "''a_o_(' x \near F ')' ex"). Reserved Notation "''o' '_(' x \near F ')' ex" (at level 0, x, ex at level 0, format "''o' '_(' x \near F ')' ex"). Reserved Notation "fx = gx '+o_(' x \near F ')' hx" (at level 70, no associativity, gx at next level, F at level 0, hx at next level, format "fx = gx '+o_(' x \near F ')' hx"). Reserved Notation "fx '=o_(' x \near F ')' hx" (at level 70, no associativity, F at level 0, hx at next level, format "fx '=o_(' x \near F ')' hx"). Reserved Notation "fx == gx '+o_(' x \near F ')' hx" (at level 70, no associativity, gx at next level, F at level 0, hx at next level, format "fx == gx '+o_(' x \near F ')' hx"). Reserved Notation "fx '==o_(' x \near F ')' hx" (at level 70, no associativity, F at level 0, hx at next level, format "fx '==o_(' x \near F ')' hx"). Reserved Notation "{O_ F f }" (at level 0, F at level 0, format "{O_ F f }"). Reserved Notation "[bigO 'of' f 'for' fT ]" (at level 0, f at level 0, format "[bigO 'of' f 'for' fT ]"). Reserved Notation "[bigO 'of' f ]" (at level 0, f at level 0, format "[bigO 'of' f ]"). Reserved Notation "'O_ x" (at level 200, x at level 0, only parsing). Reserved Notation "'O" (at level 200, only parsing). (* Parsing *) Reserved Notation "[O_ x e 'of' f ]" (at level 0, x, e at level 0, only parsing). (*Printing*) Reserved Notation "[O '_' x e 'of' f ]" (at level 0, x, e at level 0, format "[O '_' x e 'of' f ]"). (* These notations are printing only in order to display 'O without looking at the contents, use showo to display *) Reserved Notation "''O_' x e " (at level 0, x, e at level 0, format "''O_' x e "). Reserved Notation "''a_O_' x e " (at level 0, x, e at level 0, format "''a_O_' x e "). Reserved Notation "''O' '_' x" (at level 0, x at level 0, format "''O' '_' x"). Reserved Notation "f = g '+O_' F h" (at level 70, no associativity, g at next level, F at level 0, h at next level, format "f = g '+O_' F h"). Reserved Notation "f '=O_' F h" (at level 70, no associativity, F at level 0, h at next level, format "f '=O_' F h"). Reserved Notation "f == g '+O_' F h" (at level 70, no associativity, g at next level, F at level 0, h at next level, format "f == g '+O_' F h"). Reserved Notation "f '==O_' F h" (at level 70, no associativity, F at level 0, h at next level, format "f '==O_' F h"). Reserved Notation "[O_( x \near F ) ex 'of' fx ]" (at level 0, x, ex at level 0, only parsing). (*Printing*) Reserved Notation "[O '_(' x \near F ')' ex 'of' fx ]" (at level 0, x, ex at level 0, format "[O '_(' x \near F ')' ex 'of' fx ]"). (* These notations are printing only in order to display 'o without looking at the contents, use showo to display *) Reserved Notation "''O_(' x \near F ')' ex" (at level 0, x, ex at level 0, format "''O_(' x \near F ')' ex"). Reserved Notation "''a_O_(' x \near F ')' ex" (at level 0, x, ex at level 0, format "''a_O_(' x \near F ')' ex"). Reserved Notation "''O' '_(' x \near F ')' ex" (at level 0, x, ex at level 0, format "''O' '_(' x \near F ')' ex"). Reserved Notation "fx = gx '+O_(' x \near F ')' hx" (at level 70, no associativity, gx at next level, F at level 0, hx at next level, format "fx = gx '+O_(' x \near F ')' hx"). Reserved Notation "fx '=O_(' x \near F ')' hx" (at level 70, no associativity, F at level 0, hx at next level, format "fx '=O_(' x \near F ')' hx"). Reserved Notation "fx == gx '+O_(' x \near F ')' hx" (at level 70, no associativity, gx at next level, F at level 0, hx at next level, format "fx == gx '+O_(' x \near F ')' hx"). Reserved Notation "fx '==O_(' x \near F ')' hx" (at level 70, no associativity, F at level 0, hx at next level, format "fx '==O_(' x \near F ')' hx"). Reserved Notation "f '~_' F g" (at level 70, F at level 0, g at next level, format "f '~_' F g"). Reserved Notation "f '~~_' F g" (at level 70, F at level 0, g at next level, format "f '~~_' F g"). Reserved Notation "{Omega_ F f }" (at level 0, F at level 0, format "{Omega_ F f }"). Reserved Notation "[bigOmega 'of' f 'for' fT ]" (at level 0, f at level 0, format "[bigOmega 'of' f 'for' fT ]"). Reserved Notation "[bigOmega 'of' f ]" (at level 0, f at level 0, format "[bigOmega 'of' f ]"). Reserved Notation "[Omega_ x e 'of' f ]" (at level 0, x, e at level 0, only parsing). (* Printing *) Reserved Notation "[Omega '_' x e 'of' f ]" (at level 0, x, e at level 0, format "[Omega '_' x e 'of' f ]"). Reserved Notation "'Omega_ F g" (at level 0, F at level 0, format "''Omega_' F g"). Reserved Notation "f '=Omega_' F h" (at level 70, no associativity, F at level 0, h at next level, format "f '=Omega_' F h"). Reserved Notation "{Theta_ F g }" (at level 0, F at level 0, format "{Theta_ F g }"). Reserved Notation "[bigTheta 'of' f 'for' fT ]" (at level 0, f at level 0, format "[bigTheta 'of' f 'for' fT ]"). Reserved Notation "[bigTheta 'of' f ]" (at level 0, f at level 0, format "[bigTheta 'of' f ]"). Reserved Notation "[Theta_ x e 'of' f ]" (at level 0, x, e at level 0, only parsing). (*Printing*) Reserved Notation "[Theta '_' x e 'of' f ]" (at level 0, x, e at level 0, format "[Theta '_' x e 'of' f ]"). Reserved Notation "'Theta_ F g" (at level 0, F at level 0, format "''Theta_' F g"). Reserved Notation "f '=Theta_' F h" (at level 70, no associativity, F at level 0, h at next level, format "f '=Theta_' F h"). Delimit Scope R_scope with coqR. Local Open Scope ring_scope. Local Open Scope classical_set_scope. (* tags for littleo and bigO notations *) Definition the_tag : unit := tt. Definition gen_tag : unit := tt. Definition a_tag : unit := tt. Lemma showo : (gen_tag = tt) * (the_tag = tt) * (a_tag = tt). Proof. by []. Qed. (* Tentative to handle small o and big O notations *) Section Domination. Context {K : numDomainType} {T : Type} {V W : normedModType K}. Let littleo_def (F : set (set T)) (f : T -> V) (g : T -> W) := forall eps, 0 < eps -> \forall x \near F, `|f x| <= eps * `|g x|. Structure littleo_type (F : set (set T)) (g : T -> W) := Littleo { littleo_fun :> T -> V; _ : `[< littleo_def F littleo_fun g >] }. Notation "{o_ F f }" := (littleo_type F f). Canonical littleo_subtype (F : set (set T)) (g : T -> W) := [subType for (@littleo_fun F g)]. Lemma littleo_class (F : set (set T)) (g : T -> W) (f : {o_F g}) : `[< littleo_def F f g >]. Proof. by case: f => ?. Qed. Hint Resolve littleo_class : core. Definition littleo_clone (F : set (set T)) (g : T -> W) (f : T -> V) (fT : {o_F g}) c of phant_id (littleo_class fT) c := @Littleo F g f c. Notation "[littleo 'of' f 'for' fT ]" := (@littleo_clone _ _ f fT _ idfun). Notation "[littleo 'of' f ]" := (@littleo_clone _ _ f _ _ idfun). Lemma littleo0_subproof F (g : T -> W) : Filter F -> littleo_def F (0 : T -> V) g. Proof. move=> FF _/posnumP[eps] /=; apply: filterE => x; rewrite normr0. by rewrite mulr_ge0 // ltrW. Qed. Canonical littleo0 (F : filter_on T) g := Littleo (asboolT (@littleo0_subproof F g _)). Definition the_littleo (_ : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h := littleo_fun (insubd (littleo0 F h) f). Notation PhantomF := (Phantom (set (set T))). Arguments the_littleo : simpl never, clear implicits. Notation mklittleo tag x := (the_littleo tag _ (PhantomF x)). (* Parsing *) Notation "[o_ x e 'of' f ]" := (mklittleo gen_tag x f e). (*Printing*) Notation "[o '_' x e 'of' f ]" := (the_littleo _ _ (PhantomF x) f e). (* These notations are printing only in order to display 'o without looking at the contents, use showo to display *) Notation "''o_' x e " := (the_littleo the_tag _ (PhantomF x) _ e). Notation "''a_o_' x e " := (the_littleo a_tag _ (PhantomF x) _ e). Notation "''o' '_' x" := (the_littleo gen_tag _ (PhantomF x) _). Notation "f = g '+o_' F h" := (f%function = g%function + mklittleo the_tag F (f \- g) h). Notation "f '=o_' F h" := (f%function = (mklittleo the_tag F f h)). Notation "f == g '+o_' F h" := (f%function == g%function + mklittleo the_tag F (f \- g) h). Notation "f '==o_' F h" := (f%function == (mklittleo the_tag F f h)). Notation "[o_( x \near F ) ex 'of' f ]" := (mklittleo gen_tag F (fun x => f) (fun x => ex) x). Notation "[o '_(' x \near F ')' ex 'of' f ]" := (the_littleo _ _ (PhantomF F) (fun x => f) (fun x => ex) x). Notation "''o_(' x \near F ')' ex" := (the_littleo the_tag _ (PhantomF F) _ (fun x => ex) x). Notation "''a_o_(' x \near F ')' ex" := (the_littleo a_tag _ (PhantomF F) _ (fun x => ex) x). Notation "''o' '_(' x \near F ')' ex" := (the_littleo gen_tag _ (PhantomF F) _ (fun x => ex) x). Notation "fx = gx '+o_(' x \near F ')' hx" := (fx = gx + mklittleo the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '=o_(' x \near F ')' hx" := (fx = (mklittleo the_tag F (fun x => fx) (fun x => hx) x)). Notation "fx == gx '+o_(' x \near F ')' hx" := (fx == gx + mklittleo the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '==o_(' x \near F ')' hx" := (fx == (mklittleo the_tag F (fun x => fx) (fun x => hx) x)). Lemma littleoP (F : set (set T)) (g : T -> W) (f : {o_F g}) : littleo_def F f g. Proof. exact/asboolP. Qed. Hint Extern 0 (littleo_def _ _ _) => solve[apply: littleoP] : core. Hint Extern 0 (nbhs _ _) => solve[apply: littleoP] : core. Hint Extern 0 (prop_near1 _) => solve[apply: littleoP] : core. Hint Extern 0 (prop_near2 _) => solve[apply: littleoP] : core. Lemma littleoE (tag : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h : littleo_def F f h -> the_littleo tag F phF f h = f. Proof. by move=> /asboolP?; rewrite /the_littleo /insubd insubT. Qed. Canonical the_littleo_littleo (tag : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h := [littleo of the_littleo tag F phF f h]. Variant littleo_spec (F : set (set T)) (g : T -> W) : (T -> V) -> Type := LittleoSpec f of littleo_def F f g : littleo_spec F g f. Lemma littleo (F : set (set T)) (g : T -> W) (f : {o_F g}) : littleo_spec F g f. Proof. by constructor; apply/(@littleoP F). Qed. Lemma opp_littleo_subproof (F : filter_on T) e (df : {o_F e}) : littleo_def F (- (df : _ -> _)) e. Proof. by move=> _/posnumP[eps]; near=> x; rewrite normrN; near: x; apply: littleoP. Unshelve. all: by end_near. Qed. Canonical opp_littleo (F : filter_on T) e (df : {o_F e}) := Littleo (asboolT (opp_littleo_subproof df)). Lemma oppo (F : filter_on T) (f : T -> V) e : - [o_F e of f] =o_F e. Proof. by rewrite [RHS]littleoE. Qed. Lemma oppox (F : filter_on T) (f : T -> V) e x : - [o_F e of f] x = [o_F e of - [o_F e of f]] x. Proof. by move: x; rewrite -/(- _ =1 _) {1}oppo. Qed. Lemma eqadd_some_oP (F : filter_on T) (f g : T -> V) (e : T -> W) h : f = g + [o_F e of h] -> littleo_def F (f - g) e. Proof. rewrite /the_littleo /insubd=> ->. case: insubP => /= [u /asboolP fg_o_e ->|_] eps /=. by rewrite addrAC subrr add0r; apply: fg_o_e. by rewrite addrC addKr; apply: littleoP. Qed. Lemma eqaddoP (F : filter_on T) (f g : T -> V) (e : T -> W) : (f = g +o_ F e) <-> (littleo_def F (f - g) e). Proof. by split=> [/eqadd_some_oP|fg_o_e]; rewrite ?littleoE // addrC addrNK. Qed. Lemma eqoP (F : filter_on T) (e : T -> W) (f : T -> V) : (f =o_ F e) <-> (littleo_def F f e). Proof. by rewrite -[f]subr0 -eqaddoP -[f \- 0]/(f - 0) subr0 add0r. Qed. Lemma eq_some_oP (F : filter_on T) (e : T -> W) (f : T -> V) h : f = [o_F e of h] -> littleo_def F f e. Proof. by have := @eqadd_some_oP F f 0 e h; rewrite add0r subr0. Qed. (* replaces a 'o_F e by a "canonical one" *) (* mostly to prevent problems with dependent types *) Lemma eqaddoE (F : filter_on T) (f g : T -> V) h (e : T -> W) : f = g + mklittleo a_tag F h e -> f = g +o_ F e. Proof. by move=> /eqadd_some_oP /eqaddoP. Qed. Lemma eqoE (F : filter_on T) (f : T -> V) h (e : T -> W) : f = mklittleo a_tag F h e -> f =o_F e. Proof. by move=> /eq_some_oP /eqoP. Qed. Lemma eqoEx (F : filter_on T) (f : T -> V) h (e : T -> W) : (forall x, f x = mklittleo a_tag F h e x) -> (forall x, f x =o_(x \near F) e x). Proof. by have := @eqoE F f h e; rewrite !funeqE. Qed. Lemma eqaddoEx (F : filter_on T) (f g : T -> V) h (e : T -> W) : (forall x, f x = g x + mklittleo a_tag F h e x) -> (forall x, f x = g x +o_(x \near F) (e x)). Proof. by have := @eqaddoE F f g h e; rewrite !funeqE. Qed. Lemma littleo_eqo (F : filter_on T) (g : T -> W) (f : {o_F g}) : (f : _ -> _) =o_F g. Proof. by apply/eqoP. Qed. End Domination. Section Domination_numFieldType. Context {K : numFieldType} {T : Type} {V W : normedModType K}. Let bigO_def (F : set (set T)) (f : T -> V) (g : T -> W) := \forall k \near +oo, \forall x \near F, `|f x| <= k * `|g x|. Let bigO_ex_def (F : set (set T)) (f : T -> V) (g : T -> W) := exists2 k, k > 0 & \forall x \near F, `|f x| <= k * `|g x|. Lemma bigO_exP (F : set (set T)) (f : T -> V) (g : T -> W) : Filter F -> bigO_ex_def F f g <-> bigO_def F f g. Proof. split=> [[k k0 fOg] | [k [kreal fOg]]]. exists k; rewrite realE (ltW k0) /=; split=> // l ltkl; move: fOg. by apply: filter_app; near=> x => /le_trans; apply; rewrite ler_wpmul2r // ltW. exists (Num.max 1 `|k + 1|) => //. apply: fOg; rewrite (@lt_le_trans _ _ `|k + 1|) //. by rewrite (@lt_le_trans _ _ (k + 1)) ?ltr_addl // real_ler_norm ?realD. by rewrite comparable_le_maxr ?real_comparable// lexx orbT. Unshelve. end_near. Qed. Structure bigO_type (F : set (set T)) (g : T -> W) := BigO { bigO_fun :> T -> V; _ : `[< bigO_def F bigO_fun g >] }. Notation "{O_ F f }" := (bigO_type F f). Canonical bigO_subtype (F : set (set T)) (g : T -> W) := [subType for (@bigO_fun F g)]. Lemma bigO_class (F : set (set T)) (g : T -> W) (f : {O_F g}) : `[< bigO_def F f g >]. Proof. by case: f => ?. Qed. Hint Resolve bigO_class : core. Definition bigO_clone (F : set (set T)) (g : T -> W) (f : T -> V) (fT : {O_F g}) c of phant_id (bigO_class fT) c := @BigO F g f c. Notation "[bigO 'of' f 'for' fT ]" := (@bigO_clone _ _ f fT _ idfun). Notation "[bigO 'of' f ]" := (@bigO_clone _ _ f _ _ idfun). Lemma bigO0_subproof F (g : T -> W) : Filter F -> bigO_def F (0 : T -> V) g. Proof. move=> FF; near=> k; apply: filterE => x; rewrite normr0 pmulr_rge0 ?normr_ge0//. by near: k; exists 0. Unshelve. all: by end_near. Qed. Canonical bigO0 (F : filter_on T) g := BigO (asboolT (@bigO0_subproof F g _)). Definition the_bigO (u : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h := bigO_fun (insubd (bigO0 F h) f). Arguments the_bigO : simpl never, clear implicits. (* duplicate from Section Domination *) Notation PhantomF := (Phantom (set (set T))). Notation mkbigO tag x := (the_bigO tag _ (PhantomF x)). (* Parsing *) Notation "[O_ x e 'of' f ]" := (mkbigO gen_tag x f e). (*Printing*) Notation "[O '_' x e 'of' f ]" := (the_bigO _ _ (PhantomF x) f e). (* These notations are printing only in order to display 'o without looking at the contents, use showo to display *) Notation "''O_' x e " := (the_bigO the_tag _ (PhantomF x) _ e). Notation "''a_O_' x e " := (the_bigO a_tag _ (PhantomF x) _ e). Notation "''O' '_' x" := (the_bigO gen_tag _ (PhantomF x) _). Notation "[O_( x \near F ) e 'of' f ]" := (mkbigO gen_tag F (fun x => f) (fun x => e) x). Notation "[O '_(' x \near F ')' e 'of' f ]" := (the_bigO _ _ (PhantomF F) (fun x => f) (fun x => e) x). Notation "''O_(' x \near F ')' e" := (the_bigO the_tag _ (PhantomF F) _ (fun x => e) x). Notation "''a_O_(' x \near F ')' e" := (the_bigO a_tag _ (PhantomF F) _ (fun x => e) x). Notation "''O' '_(' x \near F ')' e" := (the_bigO gen_tag _ (PhantomF F) _ (fun x => e) x). Notation "f = g '+O_' F h" := (f%function = g%function + mkbigO the_tag F (f \- g) h). Notation "f '=O_' F h" := (f%function = mkbigO the_tag F f h). Notation "f == g '+O_' F h" := (f%function == g%function + mkbigO the_tag F (f \- g) h). Notation "f '==O_' F h" := (f%function == mkbigO the_tag F f h). Notation "fx = gx '+O_(' x \near F ')' hx" := (fx = gx + mkbigO the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '=O_(' x \near F ')' hx" := (fx = (mkbigO the_tag F (fun x => fx) (fun x => hx) x)). Notation "fx == gx '+O_(' x \near F ')' hx" := (fx == gx + mkbigO the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '==O_(' x \near F ')' hx" := (fx == (mkbigO the_tag F (fun x => fx) (fun x => hx) x)). Lemma bigOP (F : set (set T)) (g : T -> W) (f : {O_F g}) : bigO_def F f g. Proof. exact/asboolP. Qed. Hint Extern 0 (bigO_def _ _ _) => solve[apply: bigOP] : core. Hint Extern 0 (nbhs _ _) => solve[apply: bigOP] : core. Hint Extern 0 (prop_near1 _) => solve[apply: bigOP] : core. Hint Extern 0 (prop_near2 _) => solve[apply: bigOP] : core. Lemma bigOE (tag : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h : bigO_def F f h -> the_bigO tag F phF f h = f. Proof. by move=> /asboolP?; rewrite /the_bigO /insubd insubT. Qed. Canonical the_bigO_bigO (tag : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h := [bigO of the_bigO tag F phF f h]. Variant bigO_spec (F : set (set T)) (g : T -> W) : (T -> V) -> Prop := BigOSpec f (k : {posnum K}) of (\forall x \near F, `|f x| <= k%:num * `|g x|) : bigO_spec F g f. Lemma bigO (F : filter_on T) (g : T -> W) (f : {O_F g}) : bigO_spec F g f. Proof. by have /bigO_exP [_/posnumP[k] kP] := bigOP f; exists k. Qed. Lemma opp_bigO_subproof (F : filter_on T) e (df : {O_F e}) : bigO_def F (- (df : _ -> _)) e. Proof. have := bigOP [bigO of df]; apply: filter_app; near=> k. by apply: filter_app; near=> x; rewrite normrN. Unshelve. all: by end_near. Qed. Canonical Opp_bigO (F : filter_on T) e (df : {O_F e}) := BigO (asboolT (opp_bigO_subproof df)). Lemma oppO (F : filter_on T) (f : T -> V) e : - [O_F e of f] =O_F e. Proof. by rewrite [RHS]bigOE. Qed. Lemma oppOx (F : filter_on T) (f : T -> V) e x : - [O_F e of f] x = [O_F e of - [O_F e of f]] x. Proof. by move: x; rewrite -/(- _ =1 _) {1}oppO. Qed. Lemma add_bigO_subproof (F : filter_on T) e (df dg : {O_F e}) : bigO_def F (df \+ dg) e. Proof. near=> k; near=> x; apply: le_trans (ler_norm_add _ _) _. by rewrite (splitr k) mulrDl ler_add //; near: x; near: k; [apply: near_pinfty_div2 (bigOP df)|apply: near_pinfty_div2 (bigOP dg)]. Unshelve. all: by end_near. Qed. Canonical add_bigO (F : filter_on T) e (df dg : {O_F e}) := @BigO _ _ (_ + _) (asboolT (add_bigO_subproof df dg)). Canonical addfun_bigO (F : filter_on T) e (df dg : {O_F e}) := BigO (asboolT (add_bigO_subproof df dg)). Lemma addO (F : filter_on T) (f g: T -> V) e : [O_F e of f] + [O_F e of g] =O_F e. Proof. by rewrite [RHS]bigOE. Qed. Lemma addOx (F : filter_on T) (f g: T -> V) e x : [O_F e of f] x + [O_F e of g] x = [O_F e of [O_F e of f] + [O_F e of g]] x. Proof. by move: x; rewrite -/(_ + _ =1 _) {1}addO. Qed. Lemma eqadd_some_OP (F : filter_on T) (f g : T -> V) (e : T -> W) h : f = g + [O_F e of h] -> bigO_def F (f - g) e. Proof. rewrite /the_bigO /insubd=> ->. case: insubP => /= [u /asboolP fg_o_e ->|_]. by rewrite addrAC subrr add0r; apply: fg_o_e. by rewrite addrC addKr; apply: bigOP. Qed. Lemma eqaddOP (F : filter_on T) (f g : T -> V) (e : T -> W) : (f = g +O_ F e) <-> (bigO_def F (f - g) e). Proof. by split=> [/eqadd_some_OP|fg_O_e]; rewrite ?bigOE // addrC addrNK. Qed. Lemma eqOP (F : filter_on T) (e : T -> W) (f : T -> V) : (f =O_ F e) <-> (bigO_def F f e). Proof. by rewrite -[f]subr0 -eqaddOP -[f \- 0]/(f - 0) subr0 add0r. Qed. Lemma eqO_exP (F : filter_on T) (e : T -> W) (f : T -> V) : (f =O_ F e) <-> (bigO_ex_def F f e). Proof. apply: iff_trans (iff_sym (bigO_exP _ _ _)); apply: eqOP. Qed. Lemma eq_some_OP (F : filter_on T) (e : T -> W) (f : T -> V) h : f = [O_F e of h] -> bigO_def F f e. Proof. by have := @eqadd_some_OP F f 0 e h; rewrite add0r subr0. Qed. Lemma bigO_eqO (F : filter_on T) (g : T -> W) (f : {O_F g}) : (f : _ -> _) =O_F g. Proof. by apply/eqOP; apply: bigOP. Qed. Lemma eqO_bigO (F : filter_on T) (e : T -> W) (f : T -> V) : f =O_ F e -> bigO_def F f e. Proof. by rewrite eqOP. Qed. (* replaces a 'O_F e by a "canonical one" *) (* mostly to prevent problems with dependent types *) Lemma eqaddOE (F : filter_on T) (f g : T -> V) h (e : T -> W) : f = g + mkbigO a_tag F h e -> f = g +O_ F e. Proof. by move=> /eqadd_some_OP /eqaddOP. Qed. Lemma eqOE (F : filter_on T) (f : T -> V) h (e : T -> W) : f = mkbigO a_tag F h e -> f =O_F e. Proof. by move=> /eq_some_OP /eqOP. Qed. Lemma eqOEx (F : filter_on T) (f : T -> V) h (e : T -> W) : (forall x, f x = mkbigO a_tag F h e x) -> (forall x, f x =O_(x \near F) e x). Proof. by have := @eqOE F f h e; rewrite !funeqE. Qed. Lemma eqaddOEx (F : filter_on T) (f g : T -> V) h (e : T -> W) : (forall x, f x = g x + mkbigO a_tag F h e x) -> (forall x, f x = g x +O_(x \near F) (e x)). Proof. by have := @eqaddOE F f g h e; rewrite !funeqE. Qed. (* duplicate from Section Domination *) Notation mklittleo tag x := (the_littleo tag (PhantomF x)). (* Parsing *) Notation "[o_ x e 'of' f ]" := (mklittleo gen_tag x f e). (*Printing*) Notation "[o '_' x e 'of' f ]" := (the_littleo _ _ (PhantomF x) f e). Lemma eqoO (F : filter_on T) (f : T -> V) (e : T -> W) : [o_F e of f] =O_F e. Proof. by apply/eqOP; exists 0; split => // k kgt0; apply: littleoP. Qed. Hint Resolve eqoO : core. (* NB: duplicate from Section Domination *) Notation "{o_ F f }" := (littleo_type F f). Lemma littleo_eqO (F : filter_on T) (e : T -> W) (f : {o_F e}) : (f : _ -> _) =O_F e. Proof. by apply: eqOE; rewrite littleo_eqo. Qed. Canonical littleo_is_bigO (F : filter_on T) (e : T -> W) (f : {o_F e}) := BigO (asboolT (eqO_bigO (littleo_eqO f))). Canonical the_littleo_bigO (tag : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h := [bigO of the_littleo tag phF f h]. End Domination_numFieldType. Notation "{o_ F f }" := (@littleo_type _ _ _ _ F f). Notation "{O_ F f }" := (@bigO_type _ _ _ _ F f). Notation "[littleo 'of' f 'for' fT ]" := (@littleo_clone _ _ _ _ _ _ f fT _ idfun). Notation "[littleo 'of' f ]" := (@littleo_clone _ _ _ _ _ _ f _ _ idfun). Notation "[bigO 'of' f 'for' fT ]" := (@bigO_clone _ _ _ _ _ _ f fT _ idfun). Notation "[bigO 'of' f ]" := (@bigO_clone _ _ _ _ _ _ f _ _ idfun). Arguments the_littleo {_ _ _ _} _ _ _ _ _ : simpl never. Arguments the_bigO {_ _ _ _} _ _ _ _ _ : simpl never. Local Notation PhantomF x := (Phantom _ [filter of x]). Notation mklittleo tag x := (the_littleo tag _ (PhantomF x)). (* Parsing *) Notation "[o_ x e 'of' f ]" := (mklittleo gen_tag x f e). Notation "[o_( x \near F ) e 'of' f ]" := (mklittleo gen_tag F (fun x => f) (fun x => e) x). Notation "'o_ x" := (the_littleo _ _ (PhantomF x) _). Notation "'o" := (the_littleo _ _ _ _). (*Printing*) Notation "[o '_(' x \near F ')' e 'of' f ]" := (the_littleo _ _ (PhantomF F) (fun x => f) (fun x => e) x). Notation "[o '_' x e 'of' f ]" := (the_littleo _ _ (Phantom _ x) f e). (* These notations are printing only in order to display 'o without looking at the contents, use showo to display *) Notation "''o_' x e " := (the_littleo the_tag _ (Phantom _ x) _ e). Notation "''a_o_' x e " := (the_littleo a_tag _ (Phantom _ x) _ e). Notation "''o' '_' x" := (the_littleo gen_tag _ (Phantom _ x) _). Notation "''o_(' x \near F ')' e" := (the_littleo the_tag _ (PhantomF F) _ (fun x => e) x). Notation "''a_o_(' x \near F ')' e" := (the_littleo a_tag _ (PhantomF F) _ (fun x => e) x). Notation "''o' '_(' x \near F ')' e" := (the_littleo gen_tag _ (PhantomF F) _ (fun x => e) x). Notation mkbigO tag x := (the_bigO tag _ (PhantomF x)). (* Parsing *) Notation "[O_ x e 'of' f ]" := (mkbigO gen_tag x f e). Notation "[O_( x \near F ) e 'of' f ]" := (mkbigO gen_tag F (fun x => f) (fun x => e) x). Notation "'O_ x" := (the_bigO _ _ (PhantomF x) _). Notation "'O" := (the_bigO _ _ _ _). (*Printing*) Notation "[O '_' x e 'of' f ]" := (the_bigO _ _ (Phantom _ x) f e). Notation "[O '_(' x \near F ')' e 'of' f ]" := (the_bigO _ _ (PhantomF F) (fun x => f) (fun x => e) x). (* These notations are printing only in order to display 'o without looking at the contents, use showo to display *) Notation "''O_' x e " := (the_bigO the_tag _ (Phantom _ x) _ e). Notation "''a_O_' x e " := (the_bigO a_tag _ (Phantom _ x) _ e). Notation "''O' '_' x" := (the_bigO gen_tag _ (Phantom _ x) _). Notation "''O_(' x \near F ')' e" := (the_bigO the_tag _ (PhantomF F) _ (fun x => e) x). Notation "''a_O_(' x \near F ')' e" := (the_bigO a_tag _ (PhantomF F) _ (fun x => e) x). Notation "''O' '_(' x \near F ')' e" := (the_bigO gen_tag _ (PhantomF F) _ (fun x => e) x). Notation "f = g '+o_' F h" := (f%function = g%function + mklittleo the_tag F (f \- g) h). Notation "f '=o_' F h" := (f%function = (mklittleo the_tag F f h)). Notation "f == g '+o_' F h" := (f%function == g%function + mklittleo the_tag F (f \- g) h). Notation "f '==o_' F h" := (f%function == (mklittleo the_tag F f h)). Notation "fx = gx '+o_(' x \near F ')' hx" := (fx = gx + mklittleo the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '=o_(' x \near F ')' hx" := (fx = (mklittleo the_tag F (fun x => fx) (fun x => hx) x)). Notation "fx == gx '+o_(' x \near F ')' hx" := (fx == gx + mklittleo the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '==o_(' x \near F ')' hx" := (fx == (mklittleo the_tag F (fun x => fx) (fun x => hx) x)). Notation "f = g '+O_' F h" := (f%function = g%function + mkbigO the_tag F (f \- g) h). Notation "f '=O_' F h" := (f%function = mkbigO the_tag F f h). Notation "f == g '+O_' F h" := (f%function == g%function + mkbigO the_tag F (f \- g) h). Notation "f '==O_' F h" := (f%function == mkbigO the_tag F f h). Notation "fx = gx '+O_(' x \near F ')' hx" := (fx = gx + mkbigO the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '=O_(' x \near F ')' hx" := (fx = (mkbigO the_tag F (fun x => fx) (fun x => hx) x)). Notation "fx == gx '+O_(' x \near F ')' hx" := (fx == gx + mkbigO the_tag F ((fun x => fx) \- (fun x => gx%R)) (fun x => hx) x). Notation "fx '==O_(' x \near F ')' hx" := (fx == (mkbigO the_tag F (fun x => fx) (fun x => hx) x)). #[global] Hint Extern 0 (_ = 'o__ _) => apply: eqoE; reflexivity : core. #[global] Hint Extern 0 (_ = 'O__ _) => apply: eqOE; reflexivity : core. #[global] Hint Extern 0 (_ = 'O__ _) => apply: eqoO; reflexivity : core. #[global] Hint Extern 0 (_ = _ + 'o__ _) => apply: eqaddoE; reflexivity : core. #[global] Hint Extern 0 (_ = _ + 'O__ _) => apply: eqaddOE; reflexivity : core. #[global] Hint Extern 0 (\forall k \near +oo, \forall x \near _, is_true (`|_ x| <= k * `|_ x|)) => solve[apply: bigOP] : core. #[global] Hint Extern 0 (nbhs _ _) => solve[apply: bigOP] : core. #[global] Hint Extern 0 (prop_near1 _) => solve[apply: bigOP] : core. #[global] Hint Extern 0 (prop_near2 _) => solve[apply: bigOP] : core. #[global] Hint Extern 0 (forall e, is_true (0 < e) -> \forall x \near _, is_true (`|_ x| <= e * `|_ x|)) => solve[apply: littleoP] : core. #[global] Hint Extern 0 (nbhs _ _) => solve[apply: littleoP] : core. #[global] Hint Extern 0 (prop_near1 _) => solve[apply: littleoP] : core. #[global] Hint Extern 0 (prop_near2 _) => solve[apply: littleoP] : core. #[global] Hint Resolve littleo_class : core. #[global] Hint Resolve bigO_class : core. #[global] Hint Resolve littleo_eqO : core. Arguments bigO {_ _ _ _}. Section Domination_numFieldType. Context {K : numFieldType} {T : Type} {V W : normedModType K}. (* duplicate from Section Domination *) Let littleo_def (F : set (set T)) (f : T -> V) (g : T -> W) := forall eps, 0 < eps -> \forall x \near F, `|f x| <= eps * `|g x|. Lemma add_littleo_subproof (F : filter_on T) e (df dg : {o_F e}) : littleo_def F (df \+ dg) e. Proof. move=> _/posnumP[eps]; near=> x => /=. rewrite [eps%:num]splitr mulrDl (le_trans (ler_norm_add _ _)) // ler_add //; by near: x; apply: littleoP. Unshelve. all: by end_near. Qed. Canonical add_littleo (F : filter_on T) e (df dg : {o_F e}) := @Littleo _ _ _ _ _ _ (_ + _) (asboolT (add_littleo_subproof df dg)). Canonical addfun_littleo (F : filter_on T) e (df dg : {o_F e}) := @Littleo _ _ _ _ _ _ (_ \+ _) (asboolT (add_littleo_subproof df dg)). Lemma addo (F : filter_on T) (f g: T -> V) (e : _ -> W) : [o_F e of f] + [o_F e of g] =o_F e. Proof. by rewrite [RHS]littleoE. Qed. Lemma addox (F : filter_on T) (f g: T -> V) (e : _ -> W) x : [o_F e of f] x + [o_F e of g] x = [o_F e of [o_F e of f] + [o_F e of g]] x. Proof. by move: x; rewrite -/(_ + _ =1 _) {1}addo. Qed. (* duplicate from Section Domination *) Hint Extern 0 (littleo_def _ _ _) => solve[apply: littleoP] : core. Lemma scale_littleo_subproof (F : filter_on T) e (df : {o_F e}) a : littleo_def F (a *: (df : _ -> _)) e. Proof. have [->|a0] := eqVneq a 0; first by rewrite scale0r. move=> _ /posnumP[eps]; have aa := normr_eq0 a; near=> x => /=. rewrite normmZ -ler_pdivl_mull ?lt_def ?aa ?a0 //= mulrA; near: x. by apply: littleoP; rewrite mulr_gt0 // invr_gt0 ?lt_def ?aa ?a0 /=. Unshelve. all: by end_near. Qed. Canonical scale_littleo (F : filter_on T) e a (df : {o_F e}) := Littleo (asboolT (scale_littleo_subproof df a)). Lemma scaleo (F : filter_on T) a (f : T -> V) (e : _ -> W) : a *: [o_F e of f] = [o_F e of a *: [o_F e of f]]. Proof. by rewrite [RHS]littleoE. Qed. Lemma scaleox (F : filter_on T) a (f : T -> V) (e : _ -> W) x : a *: ([o_F e of f] x) = [o_F e of a *: [o_F e of f]] x. Proof. by move: x; rewrite -/(_ *: _ =1 _) {1}scaleo. Qed. End Domination_numFieldType. (* NB: see also scaleox *) Lemma scaleolx (K : numFieldType) (V W : normedModType K) {T : Type} (F : filter_on T) (a : W) (k : T -> K^o) (e : T -> V) (x : T) : ([o_F e of k] x) *: a = [o_F e of (fun y => [o_F e of k] y *: a)] x. Proof. rewrite [in RHS]littleoE //. have [->|a0] := eqVneq a 0. by move=> ??; apply: filterE => ?; rewrite scaler0 normr0 pmulr_rge0. move=> _/posnumP[eps]. have ea : 0 < eps%:num / `| a | by rewrite divr_gt0 // normr_gt0. have [g /(_ _ ea) ?] := littleo; near=> y. rewrite normmZ -ler_pdivl_mulr; first by rewrite mulrAC; near: y. by rewrite lt_def normr_eq0 a0 normr_ge0. Unshelve. all: by end_near. Qed. Section Limit. Context {K : numFieldType} {T : Type} {V W X : normedModType K}. Lemma eqolimP (F : filter_on T) (f : T -> V) (l : V) : f @ F --> l <-> f = cst l +o_F (cst (1 : K^o)). Proof. split=> fFl. apply/eqaddoP => _/posnumP[eps]; near=> x. rewrite /cst ltW //= distrC; near: x. by apply: (cvg_dist _ fFl); rewrite mulr_gt0 // normr1. apply/cvg_distP=> _/posnumP[eps]; rewrite /= near_simpl. have lt_eps x : x <= (eps%:num / 2%:R) * `|1 : K^o|%real -> x < eps%:num. rewrite normr1 mulr1 => /le_lt_trans; apply. by rewrite ltr_pdivr_mulr // ltr_pmulr // ltr1n. near=> x; rewrite [X in X x]fFl opprD addNKr normrN lt_eps //; near: x. by rewrite /= !near_simpl; apply: littleoP; rewrite divr_gt0. Unshelve. all: by end_near. Qed. Lemma eqolim (F : filter_on T) (f : T -> V) (l : V) e : f = cst l + [o_F (cst (1 : K^o)) of e] -> f @ F --> l. Proof. by move=> /eqaddoE /eqolimP. Qed. Lemma eqolim0P (F : filter_on T) (f : T -> V) : f @ F --> (0 : V) <-> f =o_F (cst (1 : K^o)). Proof. by rewrite eqolimP add0r -[f \- cst 0]/(f - 0) subr0. Qed. Lemma eqolim0 (F : filter_on T) (f : T -> V) : f =o_F (cst (1 : K^o)) -> f @ F --> (0 : V). Proof. by move=> /eqoE /eqolim0P. Qed. (* ideally the precondition should be f = '[O_F g of f'] with a *) (* universally quantified f' which is irrelevant and replaced by *) (* a hole, on the fly, by ssreflect rewrite *) Lemma littleo_bigO_eqo {F : filter_on T} (g : T -> W) (f : T -> V) (h : T -> X) : f =O_F g -> [o_F f of h] =o_F g. Proof. move->; apply/eqoP => _/posnumP[e]; have [k c] := bigO _ g. apply: filter_app; near=> x. rewrite -!ler_pdivr_mull //; apply: le_trans; rewrite ler_pdivr_mull // mulrA. by near: x; apply: littleoP. Unshelve. all: by end_near. Qed. Arguments littleo_bigO_eqo {F}. Lemma bigO_littleo_eqo {F : filter_on T} (g : T -> W) (f : T -> V) (h : T -> X) : f =o_F g -> [O_F f of h] =o_F g. Proof. move->; apply/eqoP => _/posnumP[e]; have [k c] := bigO. apply: filter_app; near=> x => /le_trans; apply. by rewrite -ler_pdivl_mull // mulrA; near: x; apply: littleoP. Unshelve. all: by end_near. Qed. Arguments bigO_littleo_eqo {F}. Lemma add2o (F : filter_on T) (f g : T -> V) (e : T -> W) : f =o_F e -> g =o_F e -> f + g =o_F e. Proof. by move=> -> ->; rewrite addo. Qed. Lemma addfo (F : filter_on T) (h f : T -> V) (e : T -> W) : f =o_F e -> f + [o_F e of h] =o_F e. Proof. by move->; rewrite addo. Qed. Lemma oppfo (F : filter_on T) (h f : T -> V) (e : T -> W) : f =o_F e -> - f =o_F e. Proof. by move->; rewrite oppo. Qed. Lemma add2O (F : filter_on T) (f g : T -> V) (e : T -> W) : f =O_F e -> g =O_F e -> f + g =O_F e. Proof. by move=> -> ->; rewrite addO. Qed. Lemma addfO (F : filter_on T) (h f : T -> V) (e : T -> W) : f =O_F e -> f + [O_F e of h] =O_F e. Proof. by move->; rewrite addO. Qed. Lemma oppfO (F : filter_on T) (h f : T -> V) (e : T -> W) : f =O_F e -> - f =O_F e. Proof. by move->; rewrite oppO. Qed. Lemma idO (F : filter_on T) (e : T -> W) : e =O_F e. Proof. by apply/eqO_exP; exists 1 => //; apply: filterE=> x; rewrite mul1r. Qed. Lemma littleo_littleo (F : filter_on T) (f : T -> V) (g : T -> W) (h : T -> X) : f =o_F g -> [o_F f of h] =o_F g. Proof. by move=> ->; apply: eqoE; rewrite (littleo_bigO_eqo g). Qed. End Limit. Arguments littleo_bigO_eqo {K T V W X F}. Arguments bigO_littleo_eqo {K T V W X F}. Section Limit_realFieldType. Context {K : realFieldType} (*TODO: generalize to numFieldType?*) {T : Type} {V W X : normedModType K}. Lemma bigO_bigO_eqO {F : filter_on T} (g : T -> W) (f : T -> V) (h : T -> X) : f =O_F g -> ([O_F f of h] : _ -> _) =O_F g. Proof. move->; apply/eqOP; have [k c1 kOg] := bigO _ g. have [k' c2 k'Ok] := bigO _ k. near=> c; move: k'Ok kOg; apply: filter_app2; near=> x => lek'c2k. rewrite -(@ler_pmul2l _ c2%:num) // mulrA => /(le_trans lek'c2k) /le_trans. by apply; rewrite ler_pmul//; near: c; exact: nbhs_pinfty_ge. Unshelve. all: by end_near. Qed. Arguments bigO_bigO_eqO {F}. End Limit_realFieldType. Arguments littleo_bigO_eqo {K T V W X F}. Arguments bigO_littleo_eqo {K T V W X F}. Arguments bigO_bigO_eqO {K T V W X F}. Section littleo_bigO_transitivity. Context {K : numFieldType} {T : Type} {V W Z : normedModType K}. Lemma eqaddo_trans (F : filter_on T) (f g h : T -> V) fg gh (e : T -> W): f = g + [o_ F e of fg] -> g = h + [o_F e of gh] -> f = h +o_F e. Proof. by move=> -> ->; rewrite -addrA addo. Qed. End littleo_bigO_transitivity. Section littleo_bigO_transitivity. Context {K : numFieldType} {T : Type} {V W Z : normedModType K}. Lemma eqaddO_trans (F : filter_on T) (f g h : T -> V) fg gh (e : T -> W): f = g + [O_ F e of fg] -> g = h + [O_F e of gh] -> f = h +O_F e. Proof. by move=> -> ->; rewrite -addrA addO. Qed. Lemma eqaddoO_trans (F : filter_on T) (f g h : T -> V) fg gh (e : T -> W): f = g + [o_ F e of fg] -> g = h + [O_F e of gh] -> f = h +O_F e. Proof. by move=> -> ->; rewrite addrAC -addrA addfO. Qed. Lemma eqaddOo_trans (F : filter_on T) (f g h : T -> V) fg gh (e : T -> W): f = g + [O_ F e of fg] -> g = h + [o_F e of gh] -> f = h +O_F e. Proof. by move=> -> ->; rewrite -addrA addfO. Qed. Lemma eqo_trans (F : filter_on T) (f : T -> V) f' (g : T -> W) g' (h : T -> Z) : f = [o_F g of f'] -> g = [o_F h of g'] -> f =o_F h. Proof. by move=> -> ->; rewrite (littleo_bigO_eqo h). Qed. Lemma eqOo_trans (F : filter_on T) (f : T -> V) f' (g : T -> W) g' (h : T -> Z) : f = [O_F g of f'] -> g = [o_F h of g'] -> f =o_F h. Proof. by move=> -> ->; rewrite (bigO_littleo_eqo h). Qed. Lemma eqoO_trans (F : filter_on T) (f : T -> V) f' (g : T -> W) g' (h : T -> Z) : f = [o_F g of f'] -> g = [O_F h of g'] -> f =o_F h. Proof. by move=> -> ->; rewrite (littleo_bigO_eqo h). Qed. End littleo_bigO_transitivity. Section littleo_bigO_transitivity_realFieldType. Context {K : realFieldType} (*TODO: generalize to numFieldType?*) {T : Type} {V W Z : normedModType K}. Lemma eqO_trans (F : filter_on T) (f : T -> V) f' (g : T -> W) g' (h : T -> Z) : f = [O_F g of f'] -> g = [O_F h of g'] -> f =O_F h. Proof. by move=> -> ->; rewrite (bigO_bigO_eqO h). Qed. End littleo_bigO_transitivity_realFieldType. Section rule_of_products_rcfType. Variables (R : rcfType) (pT : pointedType). (* TODO: generalize to R : numDomainType? *) Lemma mulo (F : filter_on pT) (h1 h2 f g : pT -> R^o) : [o_F h1 of f] * [o_F h2 of g] =o_F (h1 * h2). Proof. rewrite [in RHS]littleoE // => _/posnumP[e]; near=> x. rewrite [`|_|]normrM -(sqr_sqrtr (ge0 e)) expr2. rewrite (@normrM _ (h1 x) (h2 x)) mulrACA ler_pmul //; near: x; by have [/= h] := littleo; apply. Unshelve. all: by end_near. Qed. Lemma mulO (F : filter_on pT) (h1 h2 f g : pT -> R^o) : [O_F h1 of f] * [O_F h2 of g] =O_F (h1 * h2). Proof. rewrite [RHS]bigOE//; have [ O1 k1 Oh1] := bigO; have [ O2 k2 Oh2] := bigO. near=> k; move: Oh1 Oh2; apply: filter_app2; near=> x => leOh1 leOh2. rewrite [`|_|]normrM (le_trans (ler_pmul _ _ leOh1 leOh2)) //. rewrite mulrACA [`|_| in leRHS]normrM ler_wpmul2r // ?mulr_ge0 //. by near: k; exact: nbhs_pinfty_ge. Unshelve. all: by end_near. Qed. End rule_of_products_rcfType. (* NB: almost a duplicate of Section rule_of_products_rcfType *) Section rule_of_products_numClosedFieldType. Variables (R : numClosedFieldType) (pT : pointedType). Lemma mulo_numClosedFieldType (F : filter_on pT) (h1 h2 f g : pT -> R^o) : [o_F h1 of f] * [o_F h2 of g] =o_F (h1 * h2). Proof. rewrite [in RHS]littleoE // => _/posnumP[e]; near=> x. rewrite [`|_|]normrM -(sqrCK (ge0 e)) expr2 sqrtCM ?qualifE//. rewrite (@normrM _ (h1 x) (h2 x)) mulrACA ler_pmul //; near: x; by have [/= h] := littleo; apply. Unshelve. all: by end_near. Qed. Lemma mulO_numClosedFieldType (F : filter_on pT) (h1 h2 f g : pT -> R^o) : [O_F h1 of f] * [O_F h2 of g] =O_F (h1 * h2). Proof. rewrite [RHS]bigOE//; have [ O1 k1 Oh1] := bigO; have [ O2 k2 Oh2] := bigO. near=> k; move: Oh1 Oh2; apply: filter_app2; near=> x => leOh1 leOh2. rewrite [`|_|]normrM (le_trans (ler_pmul _ _ leOh1 leOh2)) //. rewrite mulrACA [`|_| in leRHS]normrM ler_wpmul2r // ?mulr_ge0 //. by near: k; exact: nbhs_pinfty_ge. Unshelve. all: by end_near. Qed. End rule_of_products_numClosedFieldType. Section Linear3. Context (R : realFieldType) (U : normedModType R) (V : normedModType R) (s : R -> V -> V) (s_law : GRing.Scale.law s). Hypothesis (normm_s : forall k x, `|s k x| = `|k| * `|x|). (* Split in multiple bits *) (* - Locally bounded => locally lipschitz *) (* - locally lipschitz + linear => lipschitz *) (* - locally lipschitz => continuous at a point *) (* - lipschitz => uniformly continous *) Local Notation "'+oo'" := (@pinfty_nbhs R). Lemma linear_for_continuous (f : {linear U -> V | GRing.Scale.op s_law}) : (f : _ -> _) =O_ (0 : U) (cst (1 : R^o)) -> continuous f. Proof. move=> /eqO_exP [_/posnumP[k0] Of1] x. apply/cvg_distP => _/posnumP[e]; rewrite !near_simpl. rewrite (near_shift 0) /= subr0; near=> y => /=. rewrite -linearB opprD addrC addrNK linearN normrN; near: y. suff flip : \forall k \near +oo, forall x, `|f x| <= k * `|x|. near +oo => k; near=> y. rewrite (le_lt_trans (near flip k _ _)) // -ltr_pdivl_mull; last first. by near: k; exists 0. near: y; apply/nbhs_normP. eexists; last by move=> ?; rewrite -ball_normE /= sub0r normrN; apply. by rewrite /= mulr_gt0 // invr_gt0; near: k; exists 0. have /nbhs_normP [_/posnumP[d]] := Of1. rewrite /cst [X in _ * X]normr1 mulr1 => fk; near=> k => y. case: (ler0P `|y|) => [|y0]. by rewrite normr_le0 => /eqP->; rewrite linear0 !normr0 mulr0. have ky0 : 0 <= k0%:num / (k * `|y|). by rewrite pmulr_rge0 // invr_ge0 mulr_ge0 // ltW //; near: k; exists 0. rewrite -[leRHS]mulr1 -ler_pdivr_mull ?pmulr_rgt0 //; last first. by near: k; exists 0. rewrite -(ler_pmul2l [gt0 of k0%:num]) mulr1 mulrA -[_ / _]ger0_norm //. rewrite -normm_s. have <- : GRing.Scale.op s_law =2 s by rewrite GRing.Scale.opE. rewrite -linearZ fk //= -ball_normE /= distrC subr0 normmZ ger0_norm //. rewrite invfM mulrA mulfVK ?lt0r_neq0 // ltr_pdivr_mulr //; last first. by near: k; exists 0. by rewrite -ltr_pdivr_mull//; near: k; exact: nbhs_pinfty_gt. Unshelve. all: by end_near. Qed. End Linear3. Arguments linear_for_continuous {R U V s s_law normm_s} f _. Lemma linear_continuous (R : realFieldType) (U : normedModType R) (V : normedModType R) (f : {linear U -> V}) : (f : _ -> _) =O_ (0 : U) (cst (1 : R^o)) -> continuous f. Proof. by apply: linear_for_continuous => ??; rewrite normmZ. Qed. Lemma linear_for_mul_continuous (R : realFieldType) (U : normedModType R) (f : {linear U -> R | (@GRing.mul [ringType of R^o])}) : (f : _ -> _) =O_ (0 : U) (cst (1 : R^o)) -> continuous f. Proof. by apply: linear_for_continuous => ??; rewrite normmZ. Qed. Notation "f '~_' F g" := (f = g +o_ F g). Notation "f '~~_' F g" := (f == g +o_ F g). Section asymptotic_equivalence. Context {K : realFieldType} {T : Type} {V W : normedModType K}. Implicit Types F : filter_on T. Lemma equivOLR F (f g : T -> V) : f ~_F g -> f =O_F g. Proof. by move=> ->; apply: eqOE; rewrite {1}[g](idO F) addrC addfO. Qed. Lemma equiv_refl F (f : T -> V) : f ~_F f. Proof. by apply/eqaddoP; rewrite subrr. Qed. Lemma equivoRL (W' : normedModType K) F (f g : T -> V) (h : T -> W') : f ~_F g -> [o_F g of h] =o_F f. Proof. move=> ->; apply/eqoP; move=> _/posnumP[eps]; near=> x. rewrite -ler_pdivr_mull // -[X in g + X]opprK oppo. rewrite (le_trans _ (ler_dist_dist _ _)) //. rewrite [leRHS]ger0_norm ?ler_subr_addr ?add0r; last first. by rewrite -[leRHS]mul1r; near: x; apply: littleoP. rewrite [leRHS]splitr [_ / 2]mulrC. by rewrite ler_add ?ler_pdivr_mull ?mulrA //; near: x; apply: littleoP. Unshelve. all: by end_near. Qed. Lemma equiv_sym F (f g : T -> V) : f ~_F g -> g ~_F f. Proof. move=> fg; have /(canLR (addrK _))<- := fg. by apply:eqaddoE; rewrite oppo (equivoRL _ fg). Qed. Lemma equivoLR (W' : normedModType K) F (f g : T -> V) (h : T -> W') : f ~_F g -> [o_F f of h] =o_F g. Proof. by move/equiv_sym/equivoRL. Qed. Lemma equivORL F (f g : T -> V) : f ~_F g -> g =O_F f. Proof. by move/equiv_sym/equivOLR. Qed. Lemma eqoaddo (W' : normedModType K) F (f g : T -> V) (h : T -> W') : [o_F f + [o_F f of g] of h] =o_F f. Proof. by apply: equivoLR. Qed. Lemma equiv_trans F (f g h : T -> V) : f ~_F g -> g ~_F h -> f ~_F h. Proof. by move=> -> ->; apply: eqaddoE; rewrite eqoaddo -addrA addo. Qed. Lemma equivalence_rel_equiv F : equivalence_rel [rel f g : T -> V | f ~~_F g]. Proof. move=> f g h; split; first by apply/eqP/equiv_refl. by move=> /eqP fg /=; apply/eqP/eqP; apply/equiv_trans => //; apply/equiv_sym. Qed. End asymptotic_equivalence. Section big_omega. Context {K : realFieldType} {T : Type} {V : normedModType K}. Implicit Types W : normedModType K. Let bigOmega_def W (F : set (set T)) (f : T -> V) (g : T -> W) := exists2 k, k > 0 & \forall x \near F, `|f x| >= k * `|g x|. Structure bigOmega_type {W} (F : set (set T)) (g : T -> W) := BigOmega { bigOmega_fun :> T -> V; _ : `[< bigOmega_def F bigOmega_fun g >] }. Notation "{Omega_ F g }" := (@bigOmega_type _ F g). Canonical bigOmega_subtype {W} (F : set (set T)) (g : T -> W) := [subType for (@bigOmega_fun W F g)]. Lemma bigOmega_class {W} (F : set (set T)) (g : T -> W) (f : {Omega_F g}) : `[< bigOmega_def F f g >]. Proof. by case: f => ?. Qed. Hint Resolve bigOmega_class : core. Definition bigOmega_clone {W} (F : set (set T)) (g : T -> W) (f : T -> V) (fT : {Omega_F g}) c of phant_id (bigOmega_class fT) c := @BigOmega W F g f c. Notation "[bigOmega 'of' f 'for' fT ]" := (@bigOmega_clone _ _ _ f fT _ idfun). Notation "[bigOmega 'of' f ]" := (@bigOmega_clone _ _ _ f _ _ idfun). Lemma bigOmega_refl_subproof F (g : T -> V) : Filter F -> bigOmega_def F g g. Proof. by move=> FF; exists 1 => //; near=> x; rewrite mul1r. Unshelve. all: by end_near. Qed. Definition bigOmega_refl (F : filter_on T) g := BigOmega (asboolT (@bigOmega_refl_subproof F g _)). Definition the_bigOmega (u : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f g := bigOmega_fun (insubd (bigOmega_refl F g) f). Arguments the_bigOmega : simpl never, clear implicits. Notation mkbigOmega tag x := (the_bigOmega tag _ (PhantomF x)). Notation "[Omega_ x e 'of' f ]" := (mkbigOmega gen_tag x f e). (* parsing *) Notation "[Omega '_' x e 'of' f ]" := (the_bigOmega _ _ (PhantomF x) f e). Definition is_bigOmega {W} (F : set (set T)) (g : T -> W) := [qualify f : T -> V | `[< bigOmega_def F f g >] ]. Fact is_bigOmega_key {W} (F : set (set T)) (g : T -> W) : pred_key (is_bigOmega F g). Proof. by []. Qed. Canonical is_bigOmega_keyed {W} (F : set (set T)) (g : T -> W) := KeyedQualifier (is_bigOmega_key F g). Notation "'Omega_ F g" := (is_bigOmega F g). Lemma bigOmegaP {W} (F : set (set T)) (g : T -> W) (f : {Omega_F g}) : bigOmega_def F f g. Proof. exact/asboolP. Qed. Hint Extern 0 (bigOmega_def _ _ _) => solve[apply: bigOmegaP] : core. Hint Extern 0 (nbhs _ _) => solve[apply: bigOmegaP] : core. Hint Extern 0 (prop_near1 _) => solve[apply: bigOmegaP] : core. Hint Extern 0 (prop_near2 _) => solve[apply: bigOmegaP] : core. Notation "f '=Omega_' F h" := (f%function = mkbigOmega the_tag F f h). Canonical the_bigOmega_bigOmega (tag : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h := [bigOmega of the_bigOmega tag F phF f h]. Variant bigOmega_spec {W} (F : set (set T)) (g : T -> W) : (T -> V) -> Prop := BigOmegaSpec f (k : {posnum K}) of (\forall x \near F, `|f x| >= k%:num * `|g x|) : bigOmega_spec F g f. Lemma bigOmega {W} (F : filter_on T) (g : T -> W) (f : {Omega_F g}) : bigOmega_spec F g f. Proof. by have [_/posnumP[k]] := bigOmegaP f; exists k. Qed. (* properties of big Omega *) Lemma eqOmegaO {W} (F : filter_on T) (f : T -> V) (e : T -> W) : (f \is 'Omega_F(e)) = (e =O_F f) :> Prop. Proof. rewrite propeqE; split => [| /eqO_exP[x x0 Hx] ]; [rewrite qualifE => /asboolP[x x0 Hx]; apply/eqO_exP | rewrite qualifE; apply/asboolP]; exists x^-1; rewrite ?invr_gt0 //; near=> y. by rewrite ler_pdivl_mull //; near: y. by rewrite ler_pdivr_mull //; near: y. Unshelve. all: by end_near. Qed. Lemma eqOmegaE (F : filter_on T) (f e : T -> V) : (f =Omega_F(e)) = (f \is 'Omega_F(e)). Proof. rewrite propeqE; split=> [->|]; rewrite qualifE; last first. by move=> H; rewrite /the_bigOmega val_insubd H. by apply/asboolP; rewrite /the_bigOmega val_insubd; case: ifPn => // /asboolP. Qed. Lemma eqOmega_trans (F : filter_on T) (f g h : T -> V) : f =Omega_F(g) -> g =Omega_F(h) -> f =Omega_F(h). Proof. rewrite !eqOmegaE !eqOmegaO => fg gh; exact: (eqO_trans gh fg). Qed. End big_omega. Notation "{Omega_ F f }" := (@bigOmega_type _ _ _ _ F f). Notation "[bigOmega 'of' f ]" := (@bigOmega_clone _ _ _ _ _ _ f _ _ idfun). Notation mkbigOmega tag x := (the_bigOmega tag (PhantomF x)). Notation "[Omega_ x e 'of' f ]" := (mkbigOmega gen_tag x f e). Notation "[Omega '_' x e 'of' f ]" := (the_bigOmega _ _ (PhantomF x) f e). Notation "'Omega_ F g" := (is_bigOmega F g). Notation "f '=Omega_' F h" := (f%function = mkbigOmega the_tag F f h). Arguments bigOmega {_ _ _ _}. Section big_omega_in_R. Variable pT : pointedType. Lemma addOmega (R : realFieldType) (F : filter_on pT) (f g h : _ -> R^o) (f_nonneg : forall x, 0 <= f x) (g_nonneg : forall x, 0 <= g x) : f =Omega_F h -> f + g =Omega_F h. Proof. rewrite 2!eqOmegaE !eqOmegaO => /eqOP hOf; apply/eqOP. apply: filter_app hOf; near=> k; apply: filter_app; near=> x => /le_trans. apply; rewrite ler_pmul2l //; last by near: k; exists 0. by rewrite !ger0_norm // ?addr_ge0 // ler_addl. Unshelve. all: by end_near. Qed. Lemma mulOmega (R : realFieldType) (F : filter_on pT) (h1 h2 f g : pT -> R^o) : [Omega_F h1 of f] * [Omega_F h2 of g] =Omega_F (h1 * h2). Proof. rewrite eqOmegaE eqOmegaO [in RHS]bigOE //. have [W1 k1 ?] := bigOmega; have [W2 k2 ?] := bigOmega. near=> k; near=> x; rewrite [`|_|]normrM. rewrite (@le_trans _ _ ((k2%:num * k1%:num)^-1 * `|(W1 * W2) x|)) //. rewrite invrM ?unitfE ?gtr_eqF // -mulrA ler_pdivl_mull //. rewrite ler_pdivl_mull // (mulrA k1%:num) mulrCA (@normrM _ (W1 x)). by rewrite ler_pmul ?mulr_ge0 //; near: x. by rewrite ler_wpmul2r // ltW //; near: k; exists (k2%:num * k1%:num)^-1. Unshelve. all: by end_near. Qed. End big_omega_in_R. Section big_theta. Context {K : realFieldType} {T : Type} {V : normedModType K}. Implicit Types W : normedModType K. Let bigTheta_def W (F : set (set T)) (f : T -> V) (g : T -> W) := exists2 k, (k.1 > 0) && (k.2 > 0) & \forall x \near F, k.1 * `|g x| <= `|f x| /\ `|f x| <= k.2 * `|g x|. Structure bigTheta_type {W} (F : set (set T)) (g : T -> W) := BigTheta { bigTheta_fun :> T -> V; _ : `[< bigTheta_def F bigTheta_fun g >] }. Notation "{Theta_ F g }" := (@bigTheta_type _ F g). Canonical bigTheta_subtype {W} (F : set (set T)) (g : T -> W) := [subType for (@bigTheta_fun W F g)]. Lemma bigTheta_class {W} (F : set (set T)) (g : T -> W) (f : {Theta_F g}) : `[< bigTheta_def F f g >]. Proof. by case: f => ?. Qed. Hint Resolve bigTheta_class : core. Definition bigTheta_clone {W} (F : set (set T)) (g : T -> W) (f : T -> V) (fT : {Theta_F g}) c of phant_id (bigTheta_class fT) c := @BigTheta W F g f c. Notation "[bigTheta 'of' f 'for' fT ]" := (@bigTheta_clone _ _ _ f fT _ idfun). Notation "[bigTheta 'of' f ]" := (@bigTheta_clone _ _ _ f _ _ idfun). Lemma bigTheta_refl_subproof F (g : T -> V) : Filter F -> bigTheta_def F g g. Proof. by move=> FF; exists 1 => /=; rewrite ?ltr01 //; near=> x; by rewrite mul1r. Unshelve. all: by end_near. Qed. Definition bigTheta_refl (F : filter_on T) g := BigTheta (asboolT (@bigTheta_refl_subproof F g _)). Definition the_bigTheta (u : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f g := bigTheta_fun (insubd (bigTheta_refl F g) f). Arguments the_bigOmega : simpl never, clear implicits. Notation mkbigTheta tag x := (@the_bigTheta tag _ (PhantomF x)). Notation "[Theta_ x e 'of' f ]" := (mkbigTheta gen_tag x f e). (* parsing *) Notation "[Theta '_' x e 'of' f ]" := (the_bigTheta _ _ (PhantomF x) f e). Definition is_bigTheta {W} (F : set (set T)) (g : T -> W) := [qualify f : T -> V | `[< bigTheta_def F f g >] ]. Fact is_bigTheta_key {W} (F : set (set T)) (g : T -> W) : pred_key (is_bigTheta F g). Proof. by []. Qed. Canonical is_bigTheta_keyed {W} (F : set (set T)) (g : T -> W) := KeyedQualifier (is_bigTheta_key F g). Notation "'Theta_ F g" := (@is_bigTheta _ F g). Lemma bigThetaP {W} (F : set (set T)) (g : T -> W) (f : {Theta_F g}) : bigTheta_def F f g. Proof. exact/asboolP. Qed. Hint Extern 0 (bigTheta_def _ _ _) => solve[apply: bigThetaP] : core. Hint Extern 0 (nbhs _ _) => solve[apply: bigThetaP] : core. Hint Extern 0 (prop_near1 _) => solve[apply: bigThetaP] : core. Hint Extern 0 (prop_near2 _) => solve[apply: bigThetaP] : core. Canonical the_bigTheta_bigTheta (tag : unit) (F : filter_on T) (phF : phantom (set (set T)) F) f h := [bigTheta of @the_bigTheta tag F phF f h]. Variant bigTheta_spec {W} (F : set (set T)) (g : T -> W) : (T -> V) -> Prop := BigThetaSpec f (k1 : {posnum K}) (k2 : {posnum K}) of (\forall x \near F, k1%:num * `|g x| <= `|f x|) & (\forall x \near F, `|f x| <= k2%:num * `|g x|) : bigTheta_spec F g f. Lemma bigTheta {W} (F : filter_on T) (g : T -> W) (f : {Theta_F g}) : bigTheta_spec F g f. Proof. have [[_ _] /andP[/posnumP[k] /posnumP[k']]] := bigThetaP f. by move=> /near_andP[]; exists k k'. Qed. Notation "f '=Theta_' F h" := (f%function = mkbigTheta the_tag F f h). Lemma bigThetaE {W} (F : filter_on T) (f : T -> V) (g : T -> W) : (f \is 'Theta_F(g)) = (f =O_F g /\ f \is 'Omega_F(g)) :> Prop. Proof. rewrite propeqE; split. - rewrite qualifE => /asboolP[[/= k1 k2] /andP[k10 k20]] /near_andP[Hx1 Hx2]. by split; [rewrite eqO_exP; exists k2| rewrite qualifE; apply/asboolP; exists k1]. - case; rewrite eqO_exP qualifE => -[k1 k10 H1] /asboolP[k2 k20 H2]. rewrite qualifE; apply/asboolP; exists (k2, k1) => /=; first by rewrite k20. by apply/near_andP; split. Qed. Lemma eqThetaE (F : filter_on T) (f e : T -> V) : (f =Theta_F(e)) = (f \is 'Theta_F(e)). Proof. rewrite propeqE; split=> [->|]; rewrite qualifE; last first. by move=> H; rewrite /the_bigTheta val_insubd H. by apply/asboolP; rewrite /the_bigTheta val_insubd; case: ifPn => // /asboolP. Qed. Lemma eqThetaO (F : filter_on T) (f g : T -> V) : [Theta_F g of f] =O_F g. Proof. by have [T1 k1 k2 ? ?] := bigTheta; apply/eqO_exP; exists k2%:num. Qed. Lemma idTheta (F : filter_on T) (f : T -> V) : f =Theta_F f. Proof. rewrite eqThetaE bigThetaE eqOmegaO; split; exact/idO. Qed. Lemma Theta_sym (F : filter_on T) (f g : T -> V) : (f =Theta_F g) = (g =Theta_F f). Proof. by rewrite !eqThetaE propeqE !bigThetaE !eqOmegaO; split => -[]. Qed. Lemma eqTheta_trans (F : filter_on T) (f g h : T -> V) : f =Theta_F g -> g =Theta_F h -> f =Theta_F h. Proof. rewrite !eqThetaE !bigThetaE -!eqOmegaE => -[fg gf] [gh hg]; split. by rewrite fg (bigO_bigO_eqO _ _ _ gh). exact: (eqOmega_trans gf hg). Qed. End big_theta. Notation "{Theta_ F g }" := (@bigTheta_type _ F g). Notation "[bigTheta 'of' f ]" := (@bigTheta_clone _ _ _ _ _ _ f _ _ idfun). Notation mkbigTheta tag x := (the_bigTheta tag (PhantomF x)). Notation "[Theta_ x e 'of' f ]" := (mkbigTheta gen_tag x f e). Notation "[Theta '_' x e 'of' f ]" := (the_bigTheta _ _ (PhantomF x) f e). Notation "'Theta_ F g" := (is_bigTheta F g). Notation "f '=Theta_' F h" := (f%function = mkbigTheta the_tag F f h). Section big_theta_in_R. Variables (R : rcfType (*realType*)) (pT : pointedType). Lemma addTheta (F : filter_on pT) (f g h : _ -> R^o) (f0 : forall x, 0 <= f x) (g0 : forall x, 0 <= g x) (h0 : forall x, 0 <= h x) : [Theta_F h of f] + [O_F h of g] =Theta_F h. Proof. rewrite eqThetaE bigThetaE; split; first by rewrite eqThetaO addO. rewrite -eqOmegaE; apply: addOmega. - by move=> ?; rewrite /the_bigTheta val_insubd /=; case: ifP. - by move=> ?; rewrite /the_bigO val_insubd /=; case: ifP. - rewrite eqOmegaE eqOmegaO; have [T1 k1 k2 ? ?] := bigTheta. rewrite bigOE //; apply/bigO_exP; exists k1%:num^-1 => //. by near=> x; rewrite ler_pdivl_mull //; near: x. Unshelve. all: by end_near. Qed. Lemma mulTheta (F : filter_on pT) (h1 h2 f g : pT -> R^o) : [Theta_F h1 of f] * [Theta_F h2 of g] =Theta_F h1 * h2. Proof. rewrite eqThetaE bigThetaE; split. by rewrite (eqThetaO _ f) (eqThetaO _ g) mulO. rewrite eqOmegaO [in RHS]bigOE //. have [T1 k1 l1 P1 ?] := bigTheta; have [T2 k2 l2 P2 ?] := bigTheta. near=> k; first near=> x. rewrite [`|_|]normrM (@le_trans _ _ ((k2%:num * k1%:num)^-1 * `|(T1 * T2) x|)) //. rewrite invrM ?unitfE ?gtr_eqF // -mulrA ler_pdivl_mull //. rewrite ler_pdivl_mull // (mulrA k1%:num) mulrCA (@normrM _ (T1 x)) ler_pmul //; by [rewrite mulr_ge0 //|near: x]. by rewrite ler_wpmul2r // ltW //; near: k; exists (k2%:num * k1%:num)^-1. Unshelve. all: by end_near. Qed. End big_theta_in_R.