Exemplo n.º 1
0
template <typename T, int stencil> void computeCoupling(dccrg::Dccrg<SpatialCell,dccrg::Cartesian_Geometry>& mpiGrid,
							const std::vector<CellID>& cells,
							FsGrid< T, stencil>& momentsGrid,
							std::map<int, std::set<CellID> >& onDccrgMapRemoteProcess,
							std::map<int, std::set<CellID> >& onFsgridMapRemoteProcess,
							std::map<CellID, std::vector<int64_t> >& onFsgridMapCells
							) {
    
  //sorted list of dccrg cells. cells is typicall already sorted, but just to make sure....
  std::vector<CellID> dccrgCells = cells;
  std::sort(dccrgCells.begin(), dccrgCells.end());

  //make sure the datastructures are clean
  onDccrgMapRemoteProcess.clear();
  onFsgridMapRemoteProcess.clear();
  onFsgridMapCells.clear();
  
  
  //size of fsgrid local part
  const std::array<int, 3> gridDims(momentsGrid.getLocalSize());
  
 
  //Compute what we will receive, and where it should be stored
  for (int k=0; k<gridDims[2]; k++) {
    for (int j=0; j<gridDims[1]; j++) {
      for (int i=0; i<gridDims[0]; i++) {
	const std::array<int, 3> globalIndices = momentsGrid.getGlobalIndices(i,j,k);
	const dccrg::Types<3>::indices_t  indices = {{(uint64_t)globalIndices[0],
						      (uint64_t)globalIndices[1],
						      (uint64_t)globalIndices[2]}}; //cast to avoid warnings
	CellID dccrgCell = mpiGrid.get_existing_cell(indices, 0, mpiGrid.mapping.get_maximum_refinement_level());
	int process = mpiGrid.get_process(dccrgCell);
	int64_t  fsgridLid = momentsGrid.LocalIDForCoords(i,j,k);
	int64_t  fsgridGid = momentsGrid.GlobalIDForCoords(i,j,k);
	onFsgridMapRemoteProcess[process].insert(dccrgCell); //cells are ordered (sorted) in set
	onFsgridMapCells[dccrgCell].push_back(fsgridLid);
      }
    }
  }

  // Compute where to send data and what to send
  for(int i=0; i< dccrgCells.size(); i++) {
     //compute to which processes this cell maps
     std::vector<CellID> fsCells = mapDccrgIdToFsGridGlobalID(mpiGrid, dccrgCells[i]);

     //loop over fsgrid cells which this dccrg cell maps to
     for (auto const &fsCellID : fsCells) {
       int process = momentsGrid.getTaskForGlobalID(fsCellID).first; //process on fsgrid
       onDccrgMapRemoteProcess[process].insert(dccrgCells[i]); //add to map
     }    
  }
}
Exemplo n.º 2
0
> void solve(
	const std::vector<uint64_t>& cell_ids,
	dccrg::Dccrg<Cell_T, dccrg::Cartesian_Geometry>& game_grid
) {
	for (auto cell_id: cell_ids) {

		Cell_T* current_data = game_grid[cell_id];
		if (current_data == NULL) {
			std::cerr << __FILE__ << ":" << __LINE__ << std::endl;
			abort();
		}

		const std::vector<uint64_t>* const neighbors
			= game_grid.get_neighbors_of(cell_id);

		for (auto neighbor_id: *neighbors) {

			if (neighbor_id == dccrg::error_cell) {
				continue;
			}

			Cell_T* neighbor_data = game_grid[neighbor_id];
			if (neighbor_data == NULL) {
				std::cerr << __FILE__ << ":" << __LINE__ << std::endl;
				abort();
			}

			if ((*neighbor_data)[Is_Alive_T()]) {
				(*current_data)[Live_Neighbors_T()]++;
			}
		}
	}
}
Exemplo n.º 3
0
void createTargetMesh(dccrg::Dccrg<SpatialCell,dccrg::Cartesian_Geometry>& mpiGrid,CellID cellID,int dim,
                      bool isRemoteCell) {
   const size_t popID = 0;

   // Get the immediate spatial face neighbors of this cell 
   // in the direction of propagation
   CellID cells[3];
   switch (dim) {
    case 0:
      cells[0] = get_spatial_neighbor(mpiGrid,cellID,true,-1,0,0);
      cells[1] = cellID;
      cells[2] = get_spatial_neighbor(mpiGrid,cellID,true,+1,0,0);
      break;
    case 1:
      cells[0] = get_spatial_neighbor(mpiGrid,cellID,true,0,-1,0);
      cells[1] = cellID;
      cells[2] = get_spatial_neighbor(mpiGrid,cellID,true,0,+1,0);
      break;
    case 2:
      cells[0] = get_spatial_neighbor(mpiGrid,cellID,true,0,0,-1);
      cells[1] = cellID;
      cells[2] = get_spatial_neighbor(mpiGrid,cellID,true,0,0,+1);
      break;
    default:
      std::cerr << "create error" << std::endl;
      exit(1);
      break;
   }

   // Remote (buffered) cells do not consider other remote cells as source cells,
   // i.e., only cells local to this process are translated
   if (isRemoteCell == true) {
      if (mpiGrid.is_local(cells[0]) == false) cells[0] = INVALID_CELLID;
      if (mpiGrid.is_local(cells[2]) == false) cells[2] = INVALID_CELLID;
   }

   SpatialCell* spatial_cell = mpiGrid[cellID];
   vmesh::VelocityMesh<vmesh::GlobalID,vmesh::LocalID>& vmesh    = spatial_cell->get_velocity_mesh_temporary();
   vmesh::VelocityBlockContainer<vmesh::LocalID>& blockContainer = spatial_cell->get_velocity_blocks_temporary();

   // At minimum the target mesh will be an identical copy of the existing mesh
   if (isRemoteCell == false) vmesh = spatial_cell->get_velocity_mesh(popID);
   else vmesh.clear();
   
   // Add or refine blocks arriving from the upstream
   addUpstreamBlocks<-1>(mpiGrid,cells[0],dim,vmesh);
   addUpstreamBlocks<+1>(mpiGrid,cells[2],dim,vmesh);

   // Target mesh generated, set block parameters
   blockContainer.setSize(vmesh.size());
   for (size_t b=0; b<vmesh.size(); ++b) {
      vmesh::GlobalID blockGID = vmesh.getGlobalID(b);
      Real* blockParams = blockContainer.getParameters(b);
      blockParams[BlockParams::VXCRD] = spatial_cell->get_velocity_block_vx_min(blockGID);
      blockParams[BlockParams::VYCRD] = spatial_cell->get_velocity_block_vy_min(blockGID);
      blockParams[BlockParams::VZCRD] = spatial_cell->get_velocity_block_vz_min(blockGID);
      vmesh.getCellSize(blockGID,&(blockParams[BlockParams::DVX]));
   }
}
Exemplo n.º 4
0
/*
Calculate the number of cells on the maximum refinement level overlapping the list of dccrg cells in cells.
*/
int getNumberOfCellsOnMaxRefLvl(dccrg::Dccrg<SpatialCell,dccrg::Cartesian_Geometry>& mpiGrid, const std::vector<CellID>& cells) {

   int nCells = 0;
   auto maxRefLvl = mpiGrid.mapping.get_maximum_refinement_level();
   
   for (auto cellid : cells) {
      auto refLvl = mpiGrid.get_refinement_level(cellid);
      nCells += pow(pow(2,maxRefLvl-refLvl),3);
   }

   return nCells;
   
}
Exemplo n.º 5
0
std::vector<CellID> mapDccrgIdToFsGridGlobalID(dccrg::Dccrg<SpatialCell,dccrg::Cartesian_Geometry>& mpiGrid,
					       CellID dccrgID) {
   const auto maxRefLvl  = mpiGrid.get_maximum_refinement_level();
   const auto refLvl = mpiGrid.get_refinement_level(dccrgID);
   const auto cellLength = pow(2,maxRefLvl-refLvl);
   const auto topLeftIndices = mpiGrid.mapping.get_indices(dccrgID);
   std::array<int,3> fsgridDims;
   
   fsgridDims[0] = P::xcells_ini * pow(2,mpiGrid.get_maximum_refinement_level());
   fsgridDims[1] = P::ycells_ini * pow(2,mpiGrid.get_maximum_refinement_level());
   fsgridDims[2] = P::zcells_ini * pow(2,mpiGrid.get_maximum_refinement_level());

   std::vector<CellID> fsgridIDs(cellLength * cellLength * cellLength);
   for (uint k = 0; k < cellLength; ++k) {
      for (uint j = 0; j < cellLength; ++j) {
         for (uint i = 0; i < cellLength; ++i) {
	   const std::array<uint64_t,3> indices = {{topLeftIndices[0] + i,topLeftIndices[1] + j,topLeftIndices[2] + k}};
	   fsgridIDs[k*cellLength*cellLength + j*cellLength + i] = indices[0] + indices[1] * fsgridDims[0] + indices[2] * fsgridDims[1] * fsgridDims[0];
	 }
      }
   }
   return fsgridIDs;
}
Exemplo n.º 6
0
/*!
\brief Read in state from a vlsv file in order to restart simulations
\param mpiGrid Vlasiator's grid
\param name Name of the restart file e.g. "restart.00052.vlsv"
 \return Returns true if the operation was successful
 \sa readGrid
 */
bool exec_readGrid(dccrg::Dccrg<SpatialCell,dccrg::Cartesian_Geometry>& mpiGrid,
      FsGrid< std::array<Real, fsgrids::bfield::N_BFIELD>, 2>& perBGrid,
      FsGrid< std::array<Real, fsgrids::efield::N_EFIELD>, 2>& EGrid,
      FsGrid< fsgrids::technical, 2>& technicalGrid,
                   const std::string& name) {
   vector<CellID> fileCells; /*< CellIds for all cells in file*/
   vector<size_t> nBlocks;/*< Number of blocks for all cells in file*/
   bool success=true;
   int myRank,processes;

#warning Spatial grid name hard-coded here
   const string meshName = "SpatialGrid";
   
   // Attempt to open VLSV file for reading:
   MPI_Comm_rank(MPI_COMM_WORLD,&myRank);
   MPI_Comm_size(MPI_COMM_WORLD,&processes);

   phiprof::start("readGrid");

   vlsv::ParallelReader file;
   MPI_Info mpiInfo = MPI_INFO_NULL;

   if (file.open(name,MPI_COMM_WORLD,MASTER_RANK,mpiInfo) == false) {
      success=false;
   }
   exitOnError(success,"(RESTART) Could not open file",MPI_COMM_WORLD);

   // Around May 2015 time was renamed from "t" to "time", we try to read both, 
   // new way is read first
   if (readScalarParameter(file,"time",P::t,MASTER_RANK,MPI_COMM_WORLD) == false)
     if (readScalarParameter(file,"t", P::t,MASTER_RANK,MPI_COMM_WORLD) == false) 
       success=false;
   P::t_min=P::t;

   // Around May 2015 timestep was renamed from "tstep" to "timestep", we to read
   // both, new way is read first
   if (readScalarParameter(file,"timestep",P::tstep,MASTER_RANK,MPI_COMM_WORLD) == false)
     if (readScalarParameter(file,"tstep", P::tstep,MASTER_RANK,MPI_COMM_WORLD) ==false) 
       success = false;
   P::tstep_min=P::tstep;

   if(readScalarParameter(file,"dt",P::dt,MASTER_RANK,MPI_COMM_WORLD) ==false) success=false;

   if(readScalarParameter(file,"fieldSolverSubcycles",P::fieldSolverSubcycles,MASTER_RANK,MPI_COMM_WORLD) ==false) {
      // Legacy restarts do not have this field, it "should" be safe for one or two steps...
      P::fieldSolverSubcycles = 1.0;
      cout << " No P::fieldSolverSubcycles found in restart, setting 1." << endl;
   }
   MPI_Bcast(&(P::fieldSolverSubcycles),1,MPI_Type<Real>(),MASTER_RANK,MPI_COMM_WORLD);
   



   checkScalarParameter(file,"xmin",P::xmin,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"ymin",P::ymin,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"zmin",P::zmin,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"xmax",P::xmax,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"ymax",P::ymax,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"zmax",P::zmax,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"xcells_ini",P::xcells_ini,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"ycells_ini",P::ycells_ini,MASTER_RANK,MPI_COMM_WORLD);
   checkScalarParameter(file,"zcells_ini",P::zcells_ini,MASTER_RANK,MPI_COMM_WORLD);

   phiprof::start("readDatalayout");
   if (success == true) success = readCellIds(file,fileCells,MASTER_RANK,MPI_COMM_WORLD);

   // Check that the cellID lists are identical in file and grid
   if (myRank==0){
      vector<CellID> allGridCells=mpiGrid.get_all_cells();
      if (fileCells.size() != allGridCells.size()){
         success=false;
      }
   }
   
   exitOnError(success,"(RESTART) Wrong number of cells in restart file",MPI_COMM_WORLD);

   // Read the total number of velocity blocks in each spatial cell.
   // Note that this is a sum over all existing particle species.
   if (success == true) {
      success = readNBlocks(file,meshName,nBlocks,MASTER_RANK,MPI_COMM_WORLD);
   }

   //make sure all cells are empty, we will anyway overwrite everything and 
   // in that case moving cells is easier...
     {
        const vector<CellID>& gridCells = getLocalCells();
        for (size_t i=0; i<gridCells.size(); i++) {
           for (uint popID=0; popID<getObjectWrapper().particleSpecies.size(); ++popID)
             mpiGrid[gridCells[i]]->clear(popID);
        }
     }

   uint64_t totalNumberOfBlocks=0;
   unsigned int numberOfBlocksPerProcess;
   for(uint i=0; i<nBlocks.size(); ++i){
      totalNumberOfBlocks += nBlocks[i];
   }
   numberOfBlocksPerProcess= 1 + totalNumberOfBlocks/processes;

   uint64_t localCellStartOffset=0; // This is where local cells start in file-list after migration.
   uint64_t localCells=0;
   uint64_t numberOfBlocksCount=0;
   
   // Pin local cells to remote processes, we try to balance number of blocks so that 
   // each process has the same amount of blocks, more or less.
   for (size_t i=0; i<fileCells.size(); ++i) {
      numberOfBlocksCount += nBlocks[i];
      int newCellProcess = numberOfBlocksCount/numberOfBlocksPerProcess;
      if (newCellProcess == myRank) {
         if (localCells == 0)
            localCellStartOffset=i; //here local cells start
         ++localCells;
      }
      if (mpiGrid.is_local(fileCells[i])) {
         mpiGrid.pin(fileCells[i],newCellProcess);
      }
   }

   SpatialCell::set_mpi_transfer_type(Transfer::ALL_SPATIAL_DATA);

   //Do initial load balance based on pins. Need to transfer at least sysboundaryflags
   mpiGrid.balance_load(false);

   //update list of local gridcells
   recalculateLocalCellsCache();

   //get new list of local gridcells
   const vector<CellID>& gridCells = getLocalCells();

   // Unpin cells, otherwise we will never change this initial bad balance
   for (size_t i=0; i<gridCells.size(); ++i) {
      mpiGrid.unpin(gridCells[i]);
   }

   // Check for errors, has migration succeeded
   if (localCells != gridCells.size() ) {
      success=false;
   } 

   if (success == true) {
      for (uint64_t i=localCellStartOffset; i<localCellStartOffset+localCells; ++i) {
         if(mpiGrid.is_local(fileCells[i]) == false) {
            success = false;
         }
      }
   }

   exitOnError(success,"(RESTART) Cell migration failed",MPI_COMM_WORLD);

   // Set cell coordinates based on cfg (mpigrid) information
   for (size_t i=0; i<gridCells.size(); ++i) {
      array<double, 3> cell_min = mpiGrid.geometry.get_min(gridCells[i]);
      array<double, 3> cell_length = mpiGrid.geometry.get_length(gridCells[i]);

      mpiGrid[gridCells[i]]->parameters[CellParams::XCRD] = cell_min[0];
      mpiGrid[gridCells[i]]->parameters[CellParams::YCRD] = cell_min[1];
      mpiGrid[gridCells[i]]->parameters[CellParams::ZCRD] = cell_min[2];
      mpiGrid[gridCells[i]]->parameters[CellParams::DX  ] = cell_length[0];
      mpiGrid[gridCells[i]]->parameters[CellParams::DY  ] = cell_length[1];
      mpiGrid[gridCells[i]]->parameters[CellParams::DZ  ] = cell_length[2];
   }

   // Where local data start in the blocklists
   //uint64_t localBlocks=0;
   //for(uint64_t i=localCellStartOffset; i<localCellStartOffset+localCells; ++i) {
   //  localBlocks += nBlocks[i];
   //}
   phiprof::stop("readDatalayout");

   //todo, check file datatype, and do not just use double
   phiprof::start("readCellParameters");
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"moments",CellParams::RHOM,5,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"moments_dt2",CellParams::RHOM_DT2,5,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"moments_r",CellParams::RHOM_R,5,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"moments_v",CellParams::RHOM_V,5,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"pressure",CellParams::P_11,3,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"pressure_dt2",CellParams::P_11_DT2,3,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"pressure_r",CellParams::P_11_R,3,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"pressure_v",CellParams::P_11_V,3,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"LB_weight",CellParams::LBWEIGHTCOUNTER,1,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"max_v_dt",CellParams::MAXVDT,1,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"max_r_dt",CellParams::MAXRDT,1,mpiGrid); }
   if(success) { success=readCellParamsVariable(file,fileCells,localCellStartOffset,localCells,"max_fields_dt",CellParams::MAXFDT,1,mpiGrid); }
// Backround B has to be set, there are also the derivatives that should be written/read if we wanted to only read in background field
   phiprof::stop("readCellParameters");

   phiprof::start("readBlockData");
   if (success == true) {
      success = readBlockData(file,meshName,fileCells,localCellStartOffset,localCells,mpiGrid); 
   }
   phiprof::stop("readBlockData");

   mpiGrid.update_copies_of_remote_neighbors(FULL_NEIGHBORHOOD_ID);
   
   // Read fsgrid data back in
   int fsgridInputRanks=0;
   if(readScalarParameter(file,"numWritingRanks",fsgridInputRanks, MASTER_RANK, MPI_COMM_WORLD) == false) {
      exitOnError(false, "(RESTART) FSGrid writing rank number not found in restart file", MPI_COMM_WORLD);
   }
   
   success = readFsGridVariable(file, "fg_PERB", fsgridInputRanks, perBGrid);
   success = readFsGridVariable(file, "fg_E", fsgridInputRanks, EGrid);
   
   success = file.close();
   phiprof::stop("readGrid");

   exitOnError(success,"(RESTART) Other failure",MPI_COMM_WORLD);
   return success;
}
Exemplo n.º 7
0
/** Read velocity block data of all existing particle species.
 * @param file VLSV reader.
 * @param meshName Name of the spatial mesh.
 * @param fileCells Vector containing spatial cell IDs.
 * @param localCellStartOffset Offset into fileCells, determines where the cells belonging 
 * to this process start.
 * @param localCells Number of spatial cells assigned to this process.
 * @param mpiGrid Parallel grid library.
 * @return If true, velocity block data was read successfully.*/
bool readBlockData(
        vlsv::ParallelReader& file,
        const string& meshName,
        const vector<CellID>& fileCells,
        const uint64_t localCellStartOffset,
        const uint64_t localCells,
        dccrg::Dccrg<SpatialCell,dccrg::Cartesian_Geometry>& mpiGrid
   ) {
   bool success = true;

   const uint64_t bytesReadStart = file.getBytesRead();
   int N_processes;
   MPI_Comm_size(MPI_COMM_WORLD,&N_processes);

   uint64_t arraySize;
   uint64_t vectorSize;
   vlsv::datatype::type dataType;
   uint64_t byteSize;
   uint64_t* offsetArray = new uint64_t[N_processes];

   for (uint popID=0; popID<getObjectWrapper().particleSpecies.size(); ++popID) {
      const string& popName = getObjectWrapper().particleSpecies[popID].name;

      // Create a cellID remapping lambda that can renumber our velocity space, should it's size have changed.
      // By default, this is a no-op that keeps the blockIDs untouched.
      std::function<vmesh::GlobalID(vmesh::GlobalID)> blockIDremapper = [](vmesh::GlobalID oldID) -> vmesh::GlobalID {return oldID;};

      // Check that velocity space extents and DV matches the grids we have created
      list<pair<string,string> > attribs;
      attribs.push_back(make_pair("mesh",popName));
      std::array<unsigned int, 6> fileMeshBBox;
      unsigned int* bufferpointer = &fileMeshBBox[0];
      if (file.read("MESH_BBOX",attribs,0,6,bufferpointer,false) == false) {
         logFile << "(RESTART) ERROR: Failed to read MESH_BBOX at " << __FILE__ << ":" << __LINE__ << endl << write;
         success = false;
      }

      const size_t meshID = getObjectWrapper().particleSpecies[popID].velocityMesh;
      const vmesh::MeshParameters& ourMeshParams = getObjectWrapper().velocityMeshes[meshID];
      if(fileMeshBBox[0] != ourMeshParams.gridLength[0] ||
            fileMeshBBox[1] != ourMeshParams.gridLength[1] ||
            fileMeshBBox[2] != ourMeshParams.gridLength[2]) {

         logFile << "(RESTART) INFO: velocity mesh sizes don't match:" << endl
                 << "    restart file has " << fileMeshBBox[0] << " x " << fileMeshBBox[1] << " x " << fileMeshBBox[2] << "," << endl
                 << "    config specifies " << ourMeshParams.gridLength[0] << " x " <<  ourMeshParams.gridLength[1] << " x " <<  ourMeshParams.gridLength[2] << endl << write;

         if(ourMeshParams.gridLength[0] < fileMeshBBox[0] ||
               ourMeshParams.gridLength[1] < fileMeshBBox[1] ||
               ourMeshParams.gridLength[2] < fileMeshBBox[2]) {
            logFile << "(RESTART) ERROR: trying to shrink velocity space." << endl << write;
            abort();
         }

         // If we are mismatched, we have to iterate through the velocity coords to see if we have a
         // chance at renumbering.
         std::vector<Real> fileVelCoordsX(fileMeshBBox[0]*fileMeshBBox[3]+1);
         std::vector<Real> fileVelCoordsY(fileMeshBBox[1]*fileMeshBBox[4]+1);
         std::vector<Real> fileVelCoordsZ(fileMeshBBox[2]*fileMeshBBox[5]+1);

         Real* tempPointer = fileVelCoordsX.data();
         if (file.read("MESH_NODE_CRDS_X",attribs,0,fileMeshBBox[0]*fileMeshBBox[3]+1,tempPointer,false) == false) {
            logFile << "(RESTART) ERROR: Failed to read MESH_NODE_CRDS_X at " << __FILE__ << ":" << __LINE__ << endl << write;
            success = false;
         }
         tempPointer = fileVelCoordsY.data();
         if (file.read("MESH_NODE_CRDS_Y",attribs,0,fileMeshBBox[1]*fileMeshBBox[4]+1,tempPointer,false) == false) {
            logFile << "(RESTART) ERROR: Failed to read MESH_NODE_CRDS_X at " << __FILE__ << ":" << __LINE__ << endl << write;
            success = false;
         }
         tempPointer = fileVelCoordsZ.data();
         if (file.read("MESH_NODE_CRDS_Z",attribs,0,fileMeshBBox[2]*fileMeshBBox[5]+1,tempPointer,false) == false) {
            logFile << "(RESTART) ERROR: Failed to read MESH_NODE_CRDS_X at " << __FILE__ << ":" << __LINE__ << endl << write;
            success = false;
         }

         const Real dVx = getObjectWrapper().velocityMeshes[meshID].cellSize[0];
         for(const auto& c : fileVelCoordsX) {
            Real cellindex = (c - getObjectWrapper().velocityMeshes[meshID].meshMinLimits[0]) / dVx;
            if(fabs(nearbyint(cellindex) - cellindex) > 1./10000.) {
               logFile << "(RESTART) ERROR: Can't resize velocity space as cell coordinates don't match." << endl
                  << "          (X coordinate " << c << " = " << cellindex <<" * " << dVx << " + " << getObjectWrapper().velocityMeshes[meshID].meshMinLimits[0] << endl
                  << "           coordinate  = cellindex *   dV  +  meshMinLimits)" << endl << write;
               abort();
            }
         }

         const Real dVy = getObjectWrapper().velocityMeshes[meshID].cellSize[1];
         for(const auto& c : fileVelCoordsY) {
            Real cellindex = (c - getObjectWrapper().velocityMeshes[meshID].meshMinLimits[1]) / dVy;
            if(fabs(nearbyint(cellindex) - cellindex) > 1./10000.) {
               logFile << "(RESTART) ERROR: Can't resize velocity space as cell coordinates don't match." << endl
                  << "           (Y coordinate " << c << " = " << cellindex <<" * " << dVy << " + " << getObjectWrapper().velocityMeshes[meshID].meshMinLimits[1] << endl
                  << "           coordinate  = cellindex *   dV  +  meshMinLimits)" << endl << write;
               abort();
            }
         }

         const Real dVz = getObjectWrapper().velocityMeshes[meshID].cellSize[2];
         for(const auto& c : fileVelCoordsY) {
            Real cellindex = (c - getObjectWrapper().velocityMeshes[meshID].meshMinLimits[2]) / dVz;
            if(fabs(nearbyint(cellindex) - cellindex) > 1./10000.) {
               logFile << "(RESTART) ERROR: Can't resize velocity space as cell coordinates don't match." << endl
                  << "           (Z coordinate " << c << " = " << cellindex <<" * " << dVz << " + " << getObjectWrapper().velocityMeshes[meshID].meshMinLimits[2] << endl
                  << "           coordinate  = cellindex *   dV  +  meshMinLimits)" << endl << write;
               abort();
            }
         }

         // If we haven't aborted above, we can apparently renumber our
         // cellIDs. Build an approprita blockIDremapper lambda for this purpose.
         std::array<int, 3> velGridOffset;
         velGridOffset[0] = (fileVelCoordsX[0] - getObjectWrapper().velocityMeshes[meshID].meshMinLimits[0]) / dVx;
         velGridOffset[1] = (fileVelCoordsY[0] - getObjectWrapper().velocityMeshes[meshID].meshMinLimits[1]) / dVy;
         velGridOffset[2] = (fileVelCoordsZ[0] - getObjectWrapper().velocityMeshes[meshID].meshMinLimits[2]) / dVz;

         if((velGridOffset[0] % ourMeshParams.blockLength[0] != 0) ||
               (velGridOffset[1] % ourMeshParams.blockLength[1] != 0) ||
               (velGridOffset[2] % ourMeshParams.blockLength[2] != 0)) {
            logFile << "(RESTART) ERROR: resizing velocity space on restart must end up with the old velocity space" << endl
                    << "                 at a block boundary of the new space!" << endl
                    << "                 (It now starts at cell [" << velGridOffset[0] << ", " << velGridOffset[1] << "," << velGridOffset[2] << "])" << endl << write;
            abort();
         }

         velGridOffset[0] /= ourMeshParams.blockLength[0];
         velGridOffset[1] /= ourMeshParams.blockLength[1];
         velGridOffset[2] /= ourMeshParams.blockLength[2];

         blockIDremapper = [fileMeshBBox,velGridOffset,ourMeshParams](vmesh::GlobalID oldID) -> vmesh::GlobalID {
            unsigned int x,y,z;
            x = oldID % fileMeshBBox[0];
            y = (oldID / fileMeshBBox[0]) % fileMeshBBox[1];
            z = oldID / (fileMeshBBox[0] * fileMeshBBox[1]);

            x += velGridOffset[0];
            y += velGridOffset[1];
            z += velGridOffset[2];

            //logFile << " Remapping " << oldID << "(" << x << "," << y << "," << z << ") to " << x + y * ourMeshParams.gridLength[0] + z* ourMeshParams.gridLength[0] * ourMeshParams.gridLength[1] << endl << write;
            return x + y * ourMeshParams.gridLength[0] + z* ourMeshParams.gridLength[0] * ourMeshParams.gridLength[1];
         };

         logFile << "    => Resizing velocity space by renumbering GlobalIDs." << endl << endl << write;
      }

      // In restart files each spatial cell has an entry in CELLSWITHBLOCKS. 
      // Each process calculates how many velocity blocks it has for this species.
      attribs.clear();
      attribs.push_back(make_pair("mesh",meshName));
      attribs.push_back(make_pair("name",popName));
      vmesh::LocalID* blocksPerCell = NULL;
      
      if (file.read("BLOCKSPERCELL",attribs,localCellStartOffset,localCells,blocksPerCell,true) == false) {
         logFile << "(RESTART) ERROR: Failed to read BLOCKSPERCELL at " << __FILE__ << ":" << __LINE__ << endl << write;
         success = false;
      }

      // Count how many velocity blocks this process gets
      uint64_t blockSum = 0;
      for (uint64_t i=0; i<localCells; ++i){
         blockSum += blocksPerCell[i];
      }
      
      // Gather all block sums to master process who will them broadcast 
      // the values to everyone
      MPI_Allgather(&blockSum,1,MPI_Type<uint64_t>(),offsetArray,1,MPI_Type<uint64_t>(),MPI_COMM_WORLD);      
      
      // Calculate the offset from which this process starts reading block data
      uint64_t myOffset = 0;
      for (int64_t i=0; i<mpiGrid.get_rank(); ++i) myOffset += offsetArray[i];
      
      if (file.getArrayInfo("BLOCKVARIABLE",attribs,arraySize,vectorSize,dataType,byteSize) == false) {
         logFile << "(RESTART)  ERROR: Failed to read BLOCKVARIABLE INFO" << endl << write;
         return false;
      }

      // Call _readBlockData
      if (dataType == vlsv::datatype::type::FLOAT) {
         switch (byteSize) {
            case sizeof(double):
               if (_readBlockData<double>(file,meshName,fileCells,localCellStartOffset,localCells,blocksPerCell,
                                          myOffset,blockSum,mpiGrid,blockIDremapper,popID) == false) success = false;
               break;
            case sizeof(float):
               if (_readBlockData<float>(file,meshName,fileCells,localCellStartOffset,localCells,blocksPerCell,
                                         myOffset,blockSum,mpiGrid,blockIDremapper,popID) == false) success = false;
               break;
         }
      } else if (dataType == vlsv::datatype::type::UINT) {
         switch (byteSize) {
            case sizeof(uint32_t):
               if (_readBlockData<uint32_t>(file,meshName,fileCells,localCellStartOffset,localCells,blocksPerCell,
                                            myOffset,blockSum,mpiGrid,blockIDremapper,popID) == false) success = false;
               break;
            case sizeof(uint64_t):
               if (_readBlockData<uint64_t>(file,meshName,fileCells,localCellStartOffset,localCells,blocksPerCell,
                                            myOffset,blockSum,mpiGrid,blockIDremapper,popID) == false) success = false;
               break;
         }
      } else if (dataType == vlsv::datatype::type::INT) {
         switch (byteSize) {
            case sizeof(int32_t):
               if (_readBlockData<int32_t>(file,meshName,fileCells,localCellStartOffset,localCells,blocksPerCell,
                                           myOffset,blockSum,mpiGrid,blockIDremapper,popID) == false) success = false;
               break;
            case sizeof(int64_t):
               if (_readBlockData<int64_t>(file,meshName,fileCells,localCellStartOffset,localCells,blocksPerCell,
                                           myOffset,blockSum,mpiGrid,blockIDremapper,popID) == false) success = false;
               break;
         }
      } else {
         logFile << "(RESTART) ERROR: Failed to read data type at readCellParamsVariable" << endl << write;
         success = false;
      }
      delete [] blocksPerCell; blocksPerCell = NULL;
   } // for-loop over particle species

   delete [] offsetArray; offsetArray = NULL;
   
   const uint64_t bytesReadEnd = file.getBytesRead() - bytesReadStart;
   logFile << "Velocity meshes and data read, approximate data rate is ";
   logFile << vlsv::printDataRate(bytesReadEnd,file.getReadTime()) << endl << write;

   return success;
}
Exemplo n.º 8
0
setOfPencils buildPencils( dccrg::Dccrg<grid_data> grid,
			   setOfPencils &pencils, vector<CellID> idsOut,
			   vector<CellID> idsIn, int dimension, 
			   vector<pair<bool,bool>> path) {

  // Not necessary since c++ passes a copy by default.
  // Copy the input ids to a working set of ids
  // vector<int> ids( idsIn );
  // Copy the already computed pencil to the output list
  // vector<int> idsOut( idsInPencil );
  
  uint i = 0;
  uint length = idsIn.size();
  
  // Walk along the input pencil. Initially length is equal to the length of the
  // Unrefined pencil. When refined cells are encountered, the length is increased
  // accordingly to go through the entire pencil.
  while (i < length) {

    uint i1 = i + 1;
    uint id = idsIn[i];

    vector<CellID> children = grid.get_all_children(id);
    bool hasChildren = ( grid.get_parent(children[0]) == id );
    
    // Check if the current cell contains refined cells
    if (hasChildren) {
      
      // Check if we have encountered this refinement level before and stored
      // the path this builder followed
      if (path.size() > grid.get_refinement_level(id)) {

	// Get children using the stored path	
	vector<CellID> myChildren = getMyChildren(children,dimension,
						  path[grid.get_refinement_level(id)].first,
						  path[grid.get_refinement_level(id)].second);
	
	// Add the children to the working set at index i1

	insertVectorIntoVector(idsIn,myChildren,i1);
	length += myChildren.size();	
      
      } else {

	// Spawn new builders to construct pencils at the new refinement level
	
	for (bool left : { true, false }) {	
	  for (bool up : { true, false }) {
	    
	    // Store the path this builder has chosen
	    vector < pair <bool,bool>> myPath = path;
	    myPath.push_back(pair<bool, bool>(up,left));
	    
	    // Get children along my path.
	    vector<CellID> myChildren = getMyChildren(children,dimension,up,left);
	    // Get the ids that have not been processed yet.
	    vector<CellID> remainingIds(idsIn.begin() + i1, idsIn.end());
	    
	    // The current builder continues along the bottom-right path.
	    // Other paths will spawn a new builder.
	    if (!up && !left) {
	      
	      // Add the children to the working set. Next iteration of the
	      // main loop (over idsIn) will start on the first child

	      // Add the children to the working set at index i1
	      insertVectorIntoVector(idsIn,myChildren,i1);
	      length += myChildren.size();
	      path = myPath;
	      
	    } else {
	      
	      // Create a new working set by adding the remainder of the old
	      // working set to the end of the current children list

	      myChildren.insert(myChildren.end(),remainingIds.begin(),remainingIds.end());

	      buildPencils(grid,pencils,idsOut,myChildren,dimension,myPath);
	      
	    };
	    
	  };	  
	};      
      };
    
    } else {

      // Add unrefined cells to the pencil directly

      idsOut.push_back(id);
      
    }; // closes if(isRefined)

    // Move to the next cell
    i++;
    
  }; // closes loop over ids

  pencils.addPencil(idsOut,0.0,0.0);
  return pencils;
  
} // closes function
Exemplo n.º 9
0
    > void initialize(
        const Geometries& geometries,
        Init_Cond& initial_conditions,
        const Background_Magnetic_Field& bg_B,
        dccrg::Dccrg<Cell, Geometry>& grid,
        const std::vector<uint64_t>& cells,
        const double time,
        const double adiabatic_index,
        const double vacuum_permeability,
        const double proton_mass,
        const bool verbose,
        const Mass_Density_Getter Mas,
        const Momentum_Density_Getter Mom,
        const Total_Energy_Density_Getter Nrj,
        const Magnetic_Field_Getter Mag,
        const Background_Magnetic_Field_Pos_X_Getter Bg_B_Pos_X,
        const Background_Magnetic_Field_Pos_Y_Getter Bg_B_Pos_Y,
        const Background_Magnetic_Field_Pos_Z_Getter Bg_B_Pos_Z,
        const Mass_Density_Flux_Getter Mas_f,
        const Momentum_Density_Flux_Getter Mom_f,
        const Total_Energy_Density_Flux_Getter Nrj_f,
        const Magnetic_Field_Flux_Getter Mag_f
    ) {
    if (verbose and grid.get_rank() == 0) {
        std::cout << "Setting default MHD state... ";
        std::cout.flush();
    }
    // set default state
    for (const auto cell_id: cells) {
        auto* const cell_data = grid[cell_id];
        if (cell_data == nullptr) {
            std::cerr <<  __FILE__ << "(" << __LINE__ << ") No data for cell: "
                      << cell_id
                      << std::endl;
            abort();
        }

        // zero fluxes and background fields
        Mas_f(*cell_data)         =
            Nrj_f(*cell_data)         =
                Mom_f(*cell_data)[0]      =
                    Mom_f(*cell_data)[1]      =
                        Mom_f(*cell_data)[2]      =
                            Mag_f(*cell_data)[0]      =
                                Mag_f(*cell_data)[1]      =
                                    Mag_f(*cell_data)[2]      = 0;

        const auto c = grid.geometry.get_center(cell_id);
        const auto r = sqrt(c[0]*c[0] + c[1]*c[1] + c[2]*c[2]);
        const auto
        lat = asin(c[2] / r),
        lon = atan2(c[1], c[0]);

        const auto mass_density
            = proton_mass
              * initial_conditions.get_default_data(
                  Number_Density(),
                  time,
                  c[0], c[1], c[2],
                  r, lat, lon
              );
        const auto velocity
            = initial_conditions.get_default_data(
                  Velocity(),
                  time,
                  c[0], c[1], c[2],
                  r, lat, lon
              );
        const auto pressure
            = initial_conditions.get_default_data(
                  Pressure(),
                  time,
                  c[0], c[1], c[2],
                  r, lat, lon
              );
        const auto magnetic_field
            = initial_conditions.get_default_data(
                  Magnetic_Field(),
                  time,
                  c[0], c[1], c[2],
                  r, lat, lon
              );

        Mas(*cell_data) = mass_density;
        Mom(*cell_data) = mass_density * velocity;
        Mag(*cell_data) = magnetic_field;
        Nrj(*cell_data) = get_total_energy_density(
                              mass_density,
                              velocity,
                              pressure,
                              magnetic_field,
                              adiabatic_index,
                              vacuum_permeability
                          );

        const auto cell_end = grid.geometry.get_max(cell_id);
        Bg_B_Pos_X(*cell_data) = bg_B.get_background_field(
        {cell_end[0], c[1], c[2]},
        vacuum_permeability
        );
        Bg_B_Pos_Y(*cell_data) = bg_B.get_background_field(
        {c[0], cell_end[1], c[2]},
        vacuum_permeability
        );
        Bg_B_Pos_Z(*cell_data) = bg_B.get_background_field(
        {c[0], c[1], cell_end[2]},
        vacuum_permeability
        );
    }

    // set non-default initial conditions
    if (verbose and grid.get_rank() == 0) {
        std::cout << "done\nSetting non-default initial MHD state... ";
        std::cout.flush();
    }

    /*
    Set non-default initial conditions
    */

    // mass density
    for (
        size_t i = 0;
        i < initial_conditions.get_number_of_regions(Number_Density());
        i++
    ) {
        const auto& init_cond = initial_conditions.get_initial_condition(Number_Density(), i);
        const auto& geometry_id = init_cond.get_geometry_id();
        const auto& cells = geometries.get_cells(geometry_id);
        for (const auto& cell: cells) {
            const auto c = grid.geometry.get_center(cell);
            const auto r = sqrt(c[0]*c[0] + c[1]*c[1] + c[2]*c[2]);
            const auto
            lat = asin(c[2] / r),
            lon = atan2(c[1], c[0]);

            const auto mass_density
                = proton_mass
                  * initial_conditions.get_data(
                      Number_Density(),
                      geometry_id,
                      time,
                      c[0], c[1], c[2],
                      r, lat, lon
                  );

            auto* const cell_data = grid[cell];
            if (cell_data == NULL) {
                std::cerr <<  __FILE__ << "(" << __LINE__ << std::endl;
                abort();
            }

            Mas(*cell_data) = mass_density;
        }
    }

    // velocity
    for (
        size_t i = 0;
        i < initial_conditions.get_number_of_regions(Velocity());
        i++
    ) {
        const auto& init_cond = initial_conditions.get_initial_condition(Velocity(), i);
        const auto& geometry_id = init_cond.get_geometry_id();
        const auto& cells = geometries.get_cells(geometry_id);
        for (const auto& cell: cells) {
            const auto c = grid.geometry.get_center(cell);
            const auto r = sqrt(c[0]*c[0] + c[1]*c[1] + c[2]*c[2]);
            const auto
            lat = asin(c[2] / r),
            lon = atan2(c[1], c[0]);

            const auto velocity = initial_conditions.get_data(
                                      Velocity(),
                                      geometry_id,
                                      time,
                                      c[0], c[1], c[2],
                                      r, lat, lon
                                  );

            auto* const cell_data = grid[cell];
            if (cell_data == NULL) {
                std::cerr <<  __FILE__ << "(" << __LINE__
                          << ") No data for cell: " << cell
                          << std::endl;
                abort();
            }

            Mom(*cell_data) = Mas(*cell_data) * velocity;
        }
    }

    // magnetic field
    for (
        size_t i = 0;
        i < initial_conditions.get_number_of_regions(Magnetic_Field());
        i++
    ) {
        const auto& init_cond = initial_conditions.get_initial_condition(Magnetic_Field(), i);
        const auto& geometry_id = init_cond.get_geometry_id();
        const auto& cells = geometries.get_cells(geometry_id);
        for (const auto& cell: cells) {
            const auto c = grid.geometry.get_center(cell);
            const auto r = sqrt(c[0]*c[0] + c[1]*c[1] + c[2]*c[2]);
            const auto
            lat = asin(c[2] / r),
            lon = atan2(c[1], c[0]);

            const auto magnetic_field = initial_conditions.get_data(
                                            Magnetic_Field(),
                                            geometry_id,
                                            time,
                                            c[0], c[1], c[2],
                                            r, lat, lon
                                        );

            auto* const cell_data = grid[cell];
            if (cell_data == NULL) {
                std::cerr <<  __FILE__ << "(" << __LINE__
                          << ") No data for cell: " << cell
                          << std::endl;
                abort();
            }

            Mag(*cell_data) = magnetic_field;
        }
    }

    // pressure
    for (
        size_t i = 0;
        i < initial_conditions.get_number_of_regions(Pressure());
        i++
    ) {
        std::cout << std::endl;
        const auto& init_cond = initial_conditions.get_initial_condition(Pressure(), i);
        const auto& geometry_id = init_cond.get_geometry_id();
        std::cout << geometry_id << std::endl;
        const auto& cells = geometries.get_cells(geometry_id);
        std::cout << cells.size() << std::endl;
        for (const auto& cell: cells) {
            const auto c = grid.geometry.get_center(cell);
            const auto r = sqrt(c[0]*c[0] + c[1]*c[1] + c[2]*c[2]);
            const auto
            lat = asin(c[2] / r),
            lon = atan2(c[1], c[0]);

            const auto pressure = initial_conditions.get_data(
                                      Pressure(),
                                      geometry_id,
                                      time,
                                      c[0], c[1], c[2],
                                      r, lat, lon
                                  );

            auto* const cell_data = grid[cell];
            if (cell_data == NULL) {
                std::cerr <<  __FILE__ << "(" << __LINE__
                          << ") No data for cell: " << cell
                          << std::endl;
                abort();
            }

            Nrj(*cell_data) = get_total_energy_density(
                                  Mas(*cell_data),
                                  Mom(*cell_data) / Mas(*cell_data),
                                  pressure,
                                  Mag(*cell_data),
                                  adiabatic_index,
                                  vacuum_permeability
                              );
        }
    }

    if (verbose and grid.get_rank() == 0) {
        std::cout << "done" << std::endl;
    }
}