Ziele Untersuchung
mit Columbo Integrität von
Datenbanken Interaktion und
Portierbarkeit Ergonomie der
Schnittstellen

Angebot Produkte Projekt Beratung

Mittel Analytik Modellierung Sprachen Algebra Logik Hardware Thinking Intellekt

Zusammenhänge Gesellschaft Wirtschaft Branche Firma


products/sources/formale sprachen/Coq/test-suite/bugs/closed/

Quellcode-Bibliothek

^© Kompilation durch diese Firma

[Weder Korrektheit noch Funktionsfähigkeit der Software werden zugesichert.]

Datei: bug_1507.v Sprache: Coq

Original von: Coq^©

(*
   Implementing reals a la Stolzenberg

   Danko Ilik, March 2007

   XField.v -- (unfinished) axiomatisation of the theories of real and
               rational intervals.
*)

Definition associative (A:Type)(op:A->A->A) :=
  forall x y z:A, op (op x y) z = op x (op y z).

Definition commutative (A:Type)(op:A->A->A) :=
  forall x y:A, op x y = op y x.

Definition trichotomous (A:Type)(R:A->A->Prop) :=
  forall x y:A, R x y \/ x=y \/ R y x.

Definition relation (A:Type) := A -> A -> Prop.
Definition reflexive (A:Type)(R:relation A) := forall x:A, R x x.
Definition transitive (A:Type)(R:relation A) :=
  forall x y z:A, R x y -> R y z -> R x z.
Definition symmetric (A:Type)(R:relation A) := forall x y:A, R x y -> R y x.

Record interval (X:Set)(le:X->X->Prop) : Set :=
  interval_make {
    interval_left : X;
    interval_right : X;
    interval_nonempty : le interval_left interval_right
  }.

Record I (grnd:Set)(le:grnd->grnd->Prop) : Type := Imake {
  Icar    := interval grnd le;
  Iplus   : Icar -> Icar -> Icar;
  Imult   : Icar -> Icar -> Icar;
  Izero   : Icar;
  Ione    : Icar;
  Iopp    : Icar -> Icar;
  Iinv    : Icar -> Icar;
  Ic      : Icar -> Icar -> Prop; (* consistency *)
  (* monoids *)
  Iplus_assoc    : associative Icar Iplus;
  Imult_assoc    : associative Icar Imult;
  (* abelian groups *)
  Iplus_comm     : commutative Icar Iplus;
  Imult_comm     : commutative Icar Imult;
  Iplus_0_l      : forall x:Icar, Ic (Iplus Izero x) x;
  Iplus_0_r      : forall x:Icar, Ic (Iplus x Izero) x;
  Imult_0_l      : forall x:Icar, Ic (Imult Ione x) x;
  Imult_0_r      : forall x:Icar, Ic (Imult x Ione) x;
  Iplus_opp_r    : forall x:Icar, Ic (Iplus x (Iopp x)) (Izero);
  Imult_inv_r    : forall x:Icar, ~(Ic x Izero) -> Ic (Imult x (Iinv x)) Ione;
  (* distributive laws *)
  Imult_plus_distr_l : forall x x' y y' z z' z'',
    Ic x x' -> Ic y y' -> Ic z z' -> Ic z z'' ->
    Ic (Imult (Iplus x y) z) (Iplus (Imult x' z') (Imult y' z''));
  (* order and lattice structure *)
  Ilt          : Icar -> Icar -> Prop;
  Ilc          := fun (x y:Icar) => Ilt x y \/ Ic x y;
  Isup         : Icar -> Icar -> Icar;
  Iinf         : Icar -> Icar -> Icar;
  Ilt_trans    : transitive _ lt;
  Ilt_trich    : forall x y:Icar, Ilt x y \/ Ic x y \/ Ilt y x;
  Isup_lub     : forall x y z:Icar, Ilc x z -> Ilc y z -> Ilc (Isup x y) z;
  Iinf_glb     : forall x y z:Icar, Ilc x y -> Ilc x z -> Ilc x (Iinf y z);
  (* order preserves operations? *)
  (* properties of Ic *)
  Ic_refl   : reflexive _ Ic;
  Ic_sym    : symmetric _ Ic
}.

Definition interval_set (X:Set)(le:X->X->Prop) :=
  (interval X le) -> Prop. (* can be Set as well *)
Check interval_set.
Check Ic.
Definition consistent (X:Set)(le:X->X->Prop)(TI:I X le)(p:interval_set X le) :=
  forall I J:interval X le, p I -> p J -> (Ic X le TI) I J.
Check consistent.
(* define 'fine' *)

Record N (grnd:Set)(le:grnd->grnd->Prop)(grndI:I grnd le) : Type := Nmake {
  Ncar    := interval_set grnd le;
  Nplus   : Ncar -> Ncar -> Ncar;
  Nmult   : Ncar -> Ncar -> Ncar;
  Nzero   : Ncar;
  None    : Ncar;
  Nopp    : Ncar -> Ncar;
  Ninv    : Ncar -> Ncar;
  Nc      : Ncar -> Ncar -> Prop; (* Ncistency *)
  (* monoids *)
  Nplus_assoc    : associative Ncar Nplus;
  Nmult_assoc    : associative Ncar Nmult;
  (* abelian groups *)
  Nplus_comm     : commutative Ncar Nplus;
  Nmult_comm     : commutative Ncar Nmult;
  Nplus_0_l      : forall x:Ncar, Nc (Nplus Nzero x) x;
  Nplus_0_r      : forall x:Ncar, Nc (Nplus x Nzero) x;
  Nmult_0_l      : forall x:Ncar, Nc (Nmult None x) x;
  Nmult_0_r      : forall x:Ncar, Nc (Nmult x None) x;
  Nplus_opp_r    : forall x:Ncar, Nc (Nplus x (Nopp x)) (Nzero);
  Nmult_inv_r    : forall x:Ncar, ~(Nc x Nzero) -> Nc (Nmult x (Ninv x)) None;
  (* distributive laws *)
  Nmult_plus_distr_l : forall x x' y y' z z' z'',
    Nc x x' -> Nc y y' -> Nc z z' -> Nc z z'' ->
    Nc (Nmult (Nplus x y) z) (Nplus (Nmult x' z') (Nmult y' z''));
  (* order and lattice structure *)
  Nlt          : Ncar -> Ncar -> Prop;
  Nlc          := fun (x y:Ncar) => Nlt x y \/ Nc x y;
  Nsup         : Ncar -> Ncar -> Ncar;
  Ninf         : Ncar -> Ncar -> Ncar;
  Nlt_trans    : transitive _ lt;
  Nlt_trich    : forall x y:Ncar, Nlt x y \/ Nc x y \/ Nlt y x;
  Nsup_lub     : forall x y z:Ncar, Nlc x z -> Nlc y z -> Nlc (Nsup x y) z;
  Ninf_glb     : forall x y z:Ncar, Nlc x y -> Nlc x z -> Nlc x (Ninf y z);
  (* order preserves operations? *)
  (* properties of Nc *)
  Nc_refl   : reflexive _ Nc;
  Nc_sym    : symmetric _ Nc
}.

¤ Dauer der Verarbeitung: 0.17 Sekunden (vorverarbeitet) ¤

Download des Quellennavigators
Download des sprechenden Kalenders
in der Quellcodebibliothek suchen

Haftungshinweis

Die Informationen auf dieser Webseite wurden nach bestem Wissen sorgfältig zusammengestellt. Es wird jedoch weder Vollständigkeit, noch Richtigkeit, noch Qualität der bereit gestellten Informationen zugesichert.