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BaseFabImplem.H

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00001 /* _______              __
00002   / ___/ /  ___  __ _  / /  ___
00003  / /__/ _ \/ _ \/  ' \/ _ \/ _ \
00004  \___/_//_/\___/_/_/_/_.__/\___/ 
00005 */
00006 //
00007 // This software is copyright (C) by the Lawrence Berkeley
00008 // National Laboratory.  Permission is granted to reproduce
00009 // this software for non-commercial purposes provided that
00010 // this notice is left intact.
00011 // 
00012 // It is acknowledged that the U.S. Government has rights to
00013 // this software under Contract DE-AC03-765F00098 between
00014 // the U.S.  Department of Energy and the University of
00015 // California.
00016 //
00017 // This software is provided as a professional and academic
00018 // contribution for joint exchange. Thus it is experimental,
00019 // is provided ``as is'', with no warranties of any kind
00020 // whatsoever, no support, no promise of updates, or printed
00021 // documentation. By using this software, you acknowledge
00022 // that the Lawrence Berkeley National Laboratory and
00023 // Regents of the University of California shall have no
00024 // liability with respect to the infringement of other
00025 // copyrights by any part of this software.
00026 //
00027 
00028 #ifndef CH_BASEFABIMPLEM_H
00029 #define CH_BASEFABIMPLEM_H
00030 #include "BaseFabMacros.H"
00031 
00032 #include "MayDay.H"
00033 //
00034 // Implementation.=====================================
00035 //
00036 
00037 template <class T>
00038 Arena* BaseFab<T>::s_Arena = NULL;
00039 
00040 template <class T>
00041 inline
00042 int
00043 BaseFab<T>::nComp () const
00044 {
00045   return nvar;
00046 }
00047 
00048 template <class T>
00049 inline
00050 const Box&
00051 BaseFab<T>::box () const
00052 {
00053   return domain;
00054 }
00055 
00056 template <class T>
00057 inline
00058 const int*
00059 BaseFab<T>::size () const
00060 {
00061   return domain.size().getVect();
00062 }
00063 
00064 template <class T>
00065 inline
00066 const IntVect&
00067 BaseFab<T>::smallEnd () const
00068 {
00069   return domain.smallEnd();
00070 }
00071 
00072 template <class T>
00073 inline
00074 const IntVect&
00075 BaseFab<T>::bigEnd () const
00076 {
00077   return domain.bigEnd();
00078 }
00079 
00080 template <class T>
00081 inline
00082 const int*
00083 BaseFab<T>::loVect () const
00084 {
00085   return domain.loVect();
00086 }
00087 
00088 template <class T>
00089 inline
00090 const int*
00091 BaseFab<T>::hiVect () const
00092 {
00093   return domain.hiVect();
00094 }
00095 
00096 template <class T>
00097 inline
00098 bool
00099 BaseFab<T>::contains (const BaseFab<T>& fab) const
00100 {
00101   return box().contains(fab.box()) && nvar <= fab.nvar;
00102 }
00103 
00104 template <class T>
00105 inline
00106 bool
00107 BaseFab<T>::contains (const Box& bx) const
00108 {
00109   return box().contains(bx);
00110 }
00111 
00112 template <class T>
00113 inline
00114 T*
00115 BaseFab<T>::dataPtr (int n)
00116 {
00117   assert(!(dptr == 0));
00118   assert((n >= 0) && (n < nvar));
00119   return &dptr[n*numpts];
00120 }
00121 
00122 template <class T>
00123 inline
00124 const int*
00125 BaseFab<T>::nCompPtr () const
00126 {
00127   assert(!(dptr == 0));
00128   return &nvar;
00129 }
00130 
00131 template <class T>
00132 inline
00133 const T*
00134 BaseFab<T>::dataPtr (int n) const
00135 {
00136   assert(!(dptr == 0));
00137   assert((n >= 0) && (n < nvar));
00138   return &dptr[n*numpts];
00139 }
00140 
00141 template <class T>
00142 inline
00143 T&
00144 BaseFab<T>::operator() (const IntVect& p,
00145                         int            n)
00146 {
00147   assert(n >= 0);
00148   assert(n < nvar);
00149   assert(!(dptr == 0));
00150   assert(domain.contains(p));
00151 
00152   return dptr[domain.index(p)+n*numpts];
00153 }
00154 
00155 template <class T>
00156 inline
00157 T&
00158 BaseFab<T>::operator() (const IntVect& p)
00159 {
00160   assert(!(dptr == 0));
00161   assert(domain.contains(p));
00162 
00163   return dptr[domain.index(p)];
00164 }
00165 
00166 template <class T>
00167 inline
00168 const T&
00169 BaseFab<T>::operator() (const IntVect& p,
00170                         int            n) const
00171 {
00172   assert(n >= 0);
00173   assert(n < nvar);
00174   assert(!(dptr == 0));
00175   assert(domain.contains(p));
00176 
00177   return dptr[domain.index(p)+n*numpts];
00178 }
00179 
00180 template <class T>
00181 inline
00182 const T&
00183 BaseFab<T>::operator() (const IntVect& p) const
00184 {
00185   assert(!(dptr == 0));
00186   assert(domain.contains(p));
00187 
00188   return dptr[domain.index(p)];
00189 }
00190 
00191 template <class T>
00192 inline
00193 void
00194 BaseFab<T>::getVal  (T*             data,
00195                      const IntVect& pos,
00196                      int            n,
00197                      int            numcomp) const
00198 {
00199   const int loc      = domain.index(pos);
00200   const long size    = domain.numPts();
00201 
00202   assert(!(dptr == 0));
00203   assert(n >= 0 && n + numcomp <= nvar);
00204 
00205   for (int k = 0; k < numcomp; k++)
00206     data[k] = dptr[loc+(n+k)*size];
00207 }
00208 
00209 template <class T>
00210 inline
00211 void
00212 BaseFab<T>::getVal (T*             data,
00213                     const IntVect& pos) const
00214 {
00215   getVal(data,pos,0,nvar);
00216 }
00217 
00218 template <class T>
00219 inline
00220 BaseFab<T>&
00221 BaseFab<T>::shift (const IntVect& v)
00222 {
00223   domain += v;
00224   return *this;
00225 }
00226 
00227 template <class T>
00228 inline
00229 BaseFab<T>&
00230 BaseFab<T>::shift (int idir,
00231                    int n_cell)
00232 {
00233   domain.shift(idir,n_cell);
00234   return *this;
00235 }
00236 
00237 template <class T>
00238 inline
00239 BaseFab<T> &
00240 BaseFab<T>::shiftHalf (const IntVect& v)
00241 {
00242   domain.shiftHalf(v);
00243   return *this;
00244 }
00245 
00246 template <class T>
00247 inline
00248 BaseFab<T> &
00249 BaseFab<T>::shiftHalf (int idir,
00250                        int n_cell)
00251 {
00252   domain.shiftHalf(idir,n_cell);
00253   return *this;
00254 }
00255 
00256 template <class T>
00257 inline
00258 void
00259 BaseFab<T>::setVal (T val)
00260 {
00261   performSetVal(val,box(), 0, nvar);
00262 }
00263 
00264 template <class T>
00265 inline
00266 void
00267 BaseFab<T>::setVal (T          x,
00268                     const Box& bx,
00269                     int        n)
00270 {
00271   performSetVal(x,bx,n,1);
00272 }
00273 
00274 template <class T>
00275 inline
00276 void
00277 BaseFab<T>::setVal (T   x,
00278                     int n)
00279 {
00280   performSetVal(x,domain,n,1);
00281 }
00282 
00283 template <class T>
00284 inline
00285 void
00286 BaseFab<T>::setVal (T          x,
00287                     const Box& b,
00288                     int        ns,
00289                     int        num)
00290 {
00291   performSetVal(x,b,ns,num);
00292 }
00293 
00294 template <class T>
00295 inline
00296 BaseFab<T>&
00297 BaseFab<T>::copy (const BaseFab<T>& src,
00298                   const Box&        srcbox,
00299                   int               srccomp,
00300                   const Box&        destbox,
00301                   int               destcomp,
00302                   int               numcomp)
00303 {
00304   assert(srcbox.sameSize(destbox));
00305   assert(src.box().contains(srcbox));
00306   assert(domain.contains(destbox));
00307   assert(srccomp >= 0 && srccomp+numcomp <= src.nComp());
00308   assert(destcomp >= 0 && destcomp+numcomp <= nvar);
00309   performCopy(src,srcbox,srccomp,destbox,destcomp,numcomp);
00310   return *this;
00311 }
00312 
00313 template <class T>
00314 inline
00315 BaseFab<T>&
00316 BaseFab<T>::copy (const BaseFab<T>& src)
00317 {
00318   assert(nvar <= src.nvar);
00319   assert(domain.sameType(src.domain));
00320   Box overlap(domain);
00321   overlap &= src.domain;
00322   if (!overlap.isEmpty())
00323     performCopy(src,overlap,0,overlap,0,nvar);
00324   return *this;
00325 }
00326 
00327 template <class T>
00328 inline
00329 BaseFab<T>&
00330 BaseFab<T>::copy (const BaseFab<T>& src,
00331                   const Box&        destbox)
00332 {
00333   assert(nvar <= src.nvar);
00334   assert(domain.contains(destbox));
00335   Box overlap(destbox);
00336   overlap &= src.domain;
00337   if (!overlap.isEmpty())
00338     performCopy(src,overlap,0,overlap,0,nvar);
00339   return *this;
00340 }
00341 
00342 template <class T>
00343 inline
00344 BaseFab<T>&
00345 BaseFab<T>::copy (const BaseFab<T>& src,
00346                   int               srccomp,
00347                   int               destcomp,
00348                   int               numcomp)
00349 {
00350   assert(srccomp >= 0 && srccomp + numcomp <= src.nvar);
00351   assert(destcomp >= 0 && destcomp + numcomp <= nvar);
00352   Box overlap(domain);
00353   overlap &= src.domain;
00354   if (!overlap.isEmpty())
00355     performCopy(src,overlap,srccomp,overlap,destcomp,numcomp);
00356   return *this;
00357 }
00358 
00359 template <class T>
00360 inline
00361 void
00362 BaseFab<T>::define ()
00363 {
00364   assert(nvar > 0);
00365   assert(dptr == 0);
00366   assert(numpts > 0);
00367   //    assert(!(The_FAB_Arena == 0));// not a sufficient test !!!
00368 #ifdef ENABLE_MEMORY_TRACKING  
00369   if(s_Arena == NULL) s_Arena = new BArena(name().c_str());
00370 #else
00371   if(s_Arena == NULL) s_Arena = new BArena("");
00372 #endif
00373   if(s_Arena == NULL)
00374     MayDay::Error("malloc in basefab failed");
00375   truesize = nvar*numpts;
00376   dptr     = static_cast<T*>(s_Arena->alloc(truesize*sizeof(T)));
00377 
00378 #ifdef ENABLE_MEMORY_TRACKING  
00379   s_Arena->bytes+=truesize*sizeof(T)+sizeof(BaseFab<T>);
00380   if(s_Arena->bytes > s_Arena->peak) 
00381     s_Arena->peak = s_Arena->bytes;
00382 #endif
00383 
00384   //
00385   // Now call T::T() on the raw memo'ry so we have valid Ts.
00386   //
00387   T* ptr = dptr;
00388 
00389   for (int i = 0; i < truesize; i++, ptr++)
00390     new (ptr) T;
00391 }
00392 
00393 template <class T>
00394 inline
00395 void
00396 BaseFab<T>::undefine ()
00397 {
00398   //    assert(!(The_FAB_Arena == 0));
00399   //
00400   // Call T::~T() on the to-be-destroyed memory.
00401   //
00402   if(dptr == 0) return;
00403   T* ptr = dptr;
00404 
00405   for (int i = 0; i < truesize; i++, ptr++)
00406     ptr->~T();
00407 
00408   s_Arena->free(dptr);
00409 
00410 #ifdef ENABLE_MEMORY_TRACKING  
00411   s_Arena->bytes-= truesize*sizeof(T)+sizeof(BaseFab<T>);
00412 #endif
00413 
00414   dptr = 0;
00415 }
00416 
00417 template <class T>
00418 inline
00419 BaseFab<T>::BaseFab ()
00420   :
00421   domain(Box()),
00422   nvar(0),
00423   numpts(0),
00424   truesize(0),
00425   dptr(0)
00426 {}
00427 
00428 template <class T>
00429 inline
00430 BaseFab<T>::BaseFab (const Box& bx,
00431                      int        n)
00432   :
00433   domain(bx),
00434   nvar(n),
00435   numpts(bx.numPts()),
00436   dptr(0)
00437 {
00438   define();
00439 }
00440 
00441 
00442 template <class T>
00443 void
00444 BaseFab<T>::resize (const Box& b,
00445                     int        n)
00446 {
00447   //     nvar   = n;
00448   //     domain = b;
00449   //     numpts = domain.numPts();
00450 
00451   //     if (dptr == 0)
00452   //     {
00453   //         define();
00454   //     }
00455   //     else if (nvar*numpts > truesize)
00456   //     {
00457   //         undefine();
00458 
00459 //         define();
00460 //     }
00461   undefine();
00462   nvar = n;
00463   domain = b;
00464   numpts = domain.numPts();
00465   define();
00466 }
00467 
00468 template <class T>
00469 inline
00470 BaseFab<T>::~BaseFab ()
00471 {
00472   undefine();
00473 }
00474 
00475 template <class T>
00476 inline
00477 void
00478 BaseFab<T>::clear ()
00479 {
00480   undefine();
00481 
00482   domain = Box();
00483   nvar   = 0;
00484   numpts = 0;
00485 }
00486 
00487 template <class T>
00488 inline
00489 void
00490 BaseFab<T>::performCopy (const BaseFab<T>& src,
00491                          const Box&        srcbox,
00492                          int               srccomp,
00493                          const Box&        destbox,
00494                          int               destcomp,
00495                          int               numcomp)
00496 {
00497   assert(src.box().contains(srcbox));
00498   assert(box().contains(destbox));
00499   assert(destbox.sameSize(srcbox));
00500   assert(srccomp >= 0 && srccomp+numcomp <= src.nComp());
00501   assert(destcomp >= 0 && destcomp+numcomp <= nComp());
00502 
00503   ForAllThisBNNXCBN(T, destbox, destcomp, numcomp, src, srcbox, srccomp)
00504     {
00505       thisR = srcR;
00506     } EndForTX
00507         }
00508 
00509 template <class T>
00510 inline
00511 void
00512 BaseFab<T>::performSetVal (T         val,
00513                            const Box& bx,
00514                            int        ns,
00515                            int        num)
00516 {
00517   assert(domain.contains(bx));
00518   assert(ns >= 0 && ns + num <= nvar);
00519 
00520   if (bx == domain)
00521     {
00522       T* data = &dptr[ns*numpts];
00523       for (long i = 0, N = num*numpts; i < N; i++)
00524         {
00525           *data++ = val;
00526         }
00527     }
00528   else
00529     {
00530       ForAllThisBNN(T,bx,ns,num)
00531         {
00532           thisR = val;
00533         } EndFor
00534             }
00535 }
00536 
00537 
00538 template <class T>
00539 inline
00540 void
00541 BaseFab<T>::copy(const Box& RegionFrom, 
00542                  const Interval& Cdest, 
00543                  const Box& RegionTo, 
00544                  const BaseFab<T>& src, 
00545                  const Interval& Csrc)
00546 {
00547   if((this == &src) && (RegionFrom == RegionTo)) return;
00548   assert(Cdest.size() == Csrc.size()); 
00549   copy(src, RegionFrom, Csrc.begin(), RegionTo, 
00550        Cdest.begin(), Cdest.size());
00551 }
00552 
00553 template <class T>
00554 inline
00555 void
00556 BaseFab<T>::linearOut(void* buf, const Box& R, const Interval& comps) const
00557 {
00558   T* buffer = (T*)buf;
00559   ForAllThisBNN(T,R,comps.begin(), comps.size())
00560     {
00561       *buffer = thisR;
00562       ++buffer;
00563     } EndFor;
00564 }
00565 
00566 template <class T>
00567 inline
00568 void
00569 BaseFab<T>::linearIn(void* buf, const Box& R, const Interval& comps)
00570 {
00571   T* buffer = (T*)buf;
00572   ForAllThisBNN(T,R,comps.begin(), comps.size())
00573     {
00574       thisR = *buffer;
00575       ++buffer;
00576     } EndFor;
00577 
00578 }
00579 
00580 template <class T>
00581 inline
00582 int
00583 BaseFab<T>::size(const Box& box, const Interval& comps) const
00584 {
00585   return box.numPts()*sizeof(T)*comps.size();
00586 }
00587 
00588 template <class T>
00589 inline
00590 std::string
00591 BaseFab<T>::name()
00592 {
00593   std::string rtn = (typeid(T)).name();
00594   return rtn;
00595 }
00596 
00597 #endif /*CH_BASEFAB_H*/
00598 

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