master-d36125/doxygen/neighbours_8h_source.html

 /*!
  *
  * Copyright (C) 2015 Technical University of Liberec.  All rights reserved.
  *
  * This program is free software; you can redistribute it and/or modify it under
  * the terms of the GNU General Public License version 3 as published by the
  * Free Software Foundation. (http://www.gnu.org/licenses/gpl-3.0.en.html)
  *
  * This program is distributed in the hope that it will be useful, but WITHOUT
  * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS
  * FOR A PARTICULAR PURPOSE.  See the GNU General Public License for more details.
  *
  *
  * @file    neighbours.h
  * @brief
  */

 #ifndef MAKE_NEIGHBOURS_H
 #define MAKE_NEIGHBOURS_H

 #include "mesh/elements.h"
 #include "mesh/mesh.h"
 #include "mesh/accessors.hh"


 class Edge;
 class SideIter;
 /**
  * Navrh algoritmu pro hledani pruniku elementu dvou siti (libovlnych dimenzi)
  * algoritmus postupuje od bodu pruniku pres usecky a polygony k mnohostenum
  *
  * Vstup: Sit1 dimenze d1 a Sit2 dimenze d2
  * predpoladam d1<=d2
  *
  * 1) hladam body na hranici pruniku tj.
  *    Intersection<d> <d_e1,d_e2> .. prunik ma dimenzi d a pronikaji se simplexy dimenze d_e1, a d_e2
  *
  *    Intersection<0><0,0>  .. totozne vrcholy El<0>
  *    Intersection<0><0,1> a <1,0> .. vrchol jedne site lezi na hrane druhe site
  *    Intersection<0><0,n> a <n,0> .. vrchol lezi na El<n> druhe site
  *
  *    Intersection<0><1,1> .. bodovy prusecik dvou usecek v rovine
  *    Intersection<0><1,2> a <2,1> ... prusecik hrany a trojuhelnika
  *    ... dalsi zvlastni pripady vcetne <0><3,3> .. tetrahedrony s vrcholem na povrchu druheho
  *
  * 2) liniove pruniky Intersection<1>:
  *    Intersection<1><1,1> .. usecky na spolecne primce
  *    Intersection<1><1,2> a <2,1>.. usecka v rovine trojuhelnika
  *    Intersection<1><1,3> a <3,1> .. usecka a tetrahedron
  *    Intersection<1><2,2> .. prusecik dvou trojuhelniku
  *    Intersection<1><2,3> a <3,2> .. trojuhelnik a hrana tetrahedronu
  *    ..
  *
  * ... doprcic je to fakt hodne moznosti a je otazka, zda je nutne je vsechny rozlisovat
  *
  * Algoritmus by mel probuhat takto:
  *
  * 1) Najdu vrchol V site 1 a element E site 2 aby V byl v E
  *    (to neni tak trivialni, pokud site nepokryvaji stejnou oblast ale snad by to slo hledat v
  *     pruniku obalovych boxu)
  * 2) najdu pruseciky P_i hran z vrcholu V s povrchem E,
  *    konstruuju vsechny potrebne pruniky elementu majici vrchol V s elementem E
  *
  *    Sousedni elementy spolu s hranami ktere do nich vedou ulozim do prioritni fronty.
  *
  * 3) Vyberu z prioritni fronty novy E, pricemz vyuzivam spositane pruseciky psislusne steny a okoli vrcholu V
  *    tj. jdu po hranach po kterych jsem do noveho lementu prisel a najdu vsechny hranove pruniky, pak konstuuju slozitejsi pruniky
  *    az mam vsechny pruniky s novym elementem ...
  *
  *    ...
  *
  *    Prioritni fronta by preferovala elementy do kterych jsem se nejvicekrat dostal, tim se snazim minimalizovat povrch projite oblasti.
  *    Je ale mozne, ze to algoritmus naopak zpomali, pokud je prioritni fronta log(n).
  *
  *    Zpracovani jednoho elementu tedy zahrnuje
  *    1) trasovani hran:
  *       pro hranu H: testuju hledam prusecik se ctyrstenem:
  *         ANO -> pamatuju si hranovy prunik a ke stene (resp. sousednimu elementu) kde hrana vychazi pridam vychozi hranu
  *         NE -> konci ve vrcholu, dalsi hrany vychazejici z vrcholu pridam na seznam hran vchazejicich do elementu
  *
  *    2) po nalezeni pruniku vsech hran, hledam pruniky vsech vchazejicich ploch:
  *       jedna plocha ma se vstupni stenou useckovy prunik na jehoz konci jsou:
  *        *vstupni hrana
  *        * okraj steny
  *       kazdopadne trasuju okraj plosneho pruniku pres povrch elementu, nebo po vstupnich hranach,
  *       pokud prunikova plocha obsahuje vrchol tvorim nove vstupni plochy ...
  *
  *    3) Podobne trasuju vchazejici objemy
  *
  *    ?? lze nejak vyuzit pokud ma element vice vstupnich sten
  *       minimalne se da kontrolovat ...
  *
  *
  *  Struktura systemu pruniku do budoucna:
  *  1) trida IntersectionManager, ma matici vektoru. Na poli A(i,j) je vektor lokalnich souradnic na elementu dimenze i
  *     pruniku dimenze j.
  *  2) Jeden intersection objekt je pak iterator dvou elementu a dva indexy lokalnich souradnic v prislusnych vektorech
  *
  *  Prozatim to zjednodusime tak, ze
  *
  *
  *  Nakonec potrebuju pocitat integral pres prunik z nejake funkce f(phi_a(x), phi_b(x)), kde phi_a je bazova funkce na jednom elementu a phi_b na druhem.
  *  To budu delat numerickou kvadraturou, takze potrebuji zobrazit prunik na jednotkovy simplex. Pro uzel kvardatury x_i musim najit body a_i a b_i na
  *  referencnich elementech A a B. Tj potrebuju lokalni souradnice (to jsou souradnice na referencnich elementech) kvadraturnich bodu. V nic pak umim spocitat hodnotu bazovych funkci
  *  a pak i hodnotu funkce f.
  *
  *
  *
  */


 /**
  * Class only for VB neighbouring.
  */
 class Neighbour
 {
 public:
     Neighbour();

     void reinit(Mesh *mesh, unsigned int elem_idx, unsigned int edge_idx);

     // side of the edge in higher dim. mesh
     inline SideIter side();

     inline unsigned int edge_idx();

     // edge of higher dimensional mesh in VB neigh.
     inline Edge edge();

     // element of lower dimension mesh in VB neigh.
     inline ElementAccessor<3> element();

 private:
     Mesh * mesh_;            ///< Pointer to Mesh to which belonged
     unsigned int elem_idx_;  ///< Index of element in Mesh::element_vec_
     unsigned int edge_idx_;  ///< Index of Edge in Mesh

     friend class Mesh;
 };


 // side of the edge in higher dim. mesh
 inline SideIter Neighbour::side() {
     OLD_ASSERT( edge().n_sides() == 1 , "VB neighbouring with %d sides.\n", edge().n_sides());
     //DebugOut().fmt("VB neighbouring with {} sides.\n", edge_->n_sides);
     return edge().side(0);
 }

 inline unsigned int Neighbour::edge_idx() {
     return edge_idx_;
 }

 // edge of lower dimensional mesh in VB neigh.
 inline Edge Neighbour::edge() {
     return mesh_->edge(edge_idx_);
 }

 // element of higher dimension mesh in VB neigh.
 inline ElementAccessor<3> Neighbour::element() {
     return mesh_->element_accessor(elem_idx_);
 }


 #endif
 //-----------------------------------------------------------------------------
 // vim: set cindent:
accessors.hh

Neighbour::elem_idx_
unsigned int elem_idx_
Index of element in Mesh::element_vec_.
Definition: neighbours.h:137

ElementAccessor< 3 >

mesh.h

Mesh
Definition: mesh.h:77

Edge
Definition: accessors.hh:265

elements.h

Mesh::element_accessor
virtual ElementAccessor< 3 > element_accessor(unsigned int idx) const
Create and return ElementAccessor to element of given idx.
Definition: mesh.cc:921

OLD_ASSERT
#define OLD_ASSERT(...)
Definition: global_defs.h:108

Neighbour::element
ElementAccessor< 3 > element()
Definition: neighbours.h:161

Neighbour::edge_idx_
unsigned int edge_idx_
Index of Edge in Mesh.
Definition: neighbours.h:138

SideIter
Definition: accessors.hh:461

Neighbour::edge_idx
unsigned int edge_idx()
Definition: neighbours.h:151

Neighbour::side
SideIter side()
Definition: neighbours.h:145

Neighbour
Definition: neighbours.h:117

Mesh::n_sides
unsigned int n_sides() const
Definition: mesh.cc:233

Neighbour::Neighbour
Neighbour()
Definition: neighbours.cc:26

Neighbour::edge
Edge edge()
Definition: neighbours.h:156

Mesh::edge
Edge edge(uint edge_idx) const
Definition: mesh.cc:257

Neighbour::reinit
void reinit(Mesh *mesh, unsigned int elem_idx, unsigned int edge_idx)
Definition: neighbours.cc:30

Edge::side
SideIter side(const unsigned int i) const
Gets side iterator of the i -th side.
Definition: accessors_impl.hh:192

Neighbour::mesh_
Mesh * mesh_
Pointer to Mesh to which belonged.
Definition: neighbours.h:136