643 lines
18 KiB
C++
643 lines
18 KiB
C++
/*
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* Copyright (C) 2010 Thorsten Liebig (Thorsten.Liebig@gmx.de)
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*/
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#include "openems.h"
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#include <iomanip>
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#include "tools/array_ops.h"
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#include "FDTD/operator_cylinder.h"
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#include "FDTD/operator_cylindermultigrid.h"
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#include "FDTD/engine_multithread.h"
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#include "FDTD/operator_multithread.h"
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#include "FDTD/operator_ext_mur_abc.h"
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#include "FDTD/operator_ext_pml_sf.h"
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#include "FDTD/operator_ext_upml.h"
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#include "FDTD/processvoltage.h"
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#include "FDTD/processcurrent.h"
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#include "FDTD/process_efield.h"
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#include "FDTD/process_hfield.h"
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#include "FDTD/processmodematch.h"
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#include "FDTD/processfields_td.h"
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#include <sys/time.h>
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#include <time.h>
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#include <H5Cpp.h> // only for H5get_libversion()
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#include <boost/version.hpp> // only for BOOST_LIB_VERSION
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#include "FDTD/operator_ext_lorentzmaterial.h"
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//external libs
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#include "tinyxml.h"
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#include "ContinuousStructure.h"
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double CalcDiffTime(timeval t1, timeval t2)
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{
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double s_diff = t1.tv_sec - t2.tv_sec;
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s_diff += (t1.tv_usec-t2.tv_usec)*1e-6;
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return s_diff;
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}
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openEMS::openEMS()
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{
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FDTD_Op=NULL;
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FDTD_Eng=NULL;
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PA=NULL;
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CylinderCoords = false;
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Enable_Dumps = true;
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DebugMat = false;
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DebugOp = false;
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m_debugCSX = false;
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m_debugBox = m_debugPEC = m_no_simulation = false;
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endCrit = 1e-6;
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m_OverSampling = 4;
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m_engine = EngineType_Standard;
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m_engine_numThreads = 0;
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m_Abort = false;
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}
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openEMS::~openEMS()
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{
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Reset();
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}
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void openEMS::Reset()
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{
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if (PA) PA->DeleteAll();
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delete PA; PA=0;
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delete FDTD_Eng; FDTD_Eng=0;
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delete FDTD_Op; FDTD_Op=0;
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}
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//! \brief processes a command line argument
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//! \return true if argument is known
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//! \return false if argument is unknown
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bool openEMS::parseCommandLineArgument( const char *argv )
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{
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if (!argv)
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return false;
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if (strcmp(argv,"--disable-dumps")==0)
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{
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cout << "openEMS - disabling all field dumps" << endl;
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SetEnableDumps(false);
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return true;
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}
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else if (strcmp(argv,"--debug-material")==0)
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{
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cout << "openEMS - dumping material to 'material_dump.vtk'" << endl;
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DebugMaterial();
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return true;
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}
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else if (strcmp(argv,"--debug-operator")==0)
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{
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cout << "openEMS - dumping operator to 'operator_dump.vtk'" << endl;
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DebugOperator();
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return true;
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}
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else if (strcmp(argv,"--debug-boxes")==0)
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{
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cout << "openEMS - dumping boxes to 'box_dump*.vtk'" << endl;
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DebugBox();
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return true;
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}
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else if (strcmp(argv,"--debug-PEC")==0)
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{
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cout << "openEMS - dumping PEC info to 'PEC_dump.vtk'" << endl;
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m_debugPEC = true;
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return true;
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}
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else if (strcmp(argv,"--debug-CSX")==0)
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{
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cout << "openEMS - dumping CSX geometry to 'debugCSX.xml'" << endl;
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m_debugCSX = true;
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return true;
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}
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else if (strcmp(argv,"--engine=multithreaded")==0)
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{
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cout << "openEMS - enabled multithreading" << endl;
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m_engine = EngineType_Multithreaded;
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return true;
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}
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else if (strncmp(argv,"--numThreads=",13)==0)
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{
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m_engine_numThreads = atoi(argv+13);
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cout << "openEMS - fixed number of threads: " << m_engine_numThreads << endl;
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return true;
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}
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else if (strcmp(argv,"--engine=sse")==0)
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{
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cout << "openEMS - enabled sse engine" << endl;
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m_engine = EngineType_SSE;
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return true;
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}
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else if (strcmp(argv,"--engine=sse-compressed")==0)
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{
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cout << "openEMS - enabled compressed sse engine" << endl;
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m_engine = EngineType_SSE_Compressed;
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return true;
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}
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else if (strcmp(argv,"--engine=fastest")==0)
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{
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cout << "openEMS - enabled multithreading engine" << endl;
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m_engine = EngineType_Multithreaded;
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return true;
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}
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else if (strcmp(argv,"--no-simulation")==0)
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{
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cout << "openEMS - disabling simulation => preprocessing only" << endl;
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m_no_simulation = true;
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return true;
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}
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return false;
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}
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string openEMS::GetExtLibsInfo()
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{
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stringstream str;
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str << "\tUsed external libraries:" << endl;
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str << "\t\t" << ContinuousStructure::GetInfoLine(true) << endl;
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// libhdf5
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unsigned int major, minor, release;
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if (H5get_libversion( &major, &minor, &release ) >= 0)
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{
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str << "\t\t" << "hdf5 -- Version: " << major << '.' << minor << '.' << release << endl;
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str << "\t\t" << " compiled against: " H5_VERS_INFO << endl;
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}
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// tinyxml
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str << "\t\t" << "tinyxml -- compiled against: " << TIXML_MAJOR_VERSION << '.' << TIXML_MINOR_VERSION << '.' << TIXML_PATCH_VERSION << endl;
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// boost
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str << "\t\t" << "boost -- compiled against: " BOOST_LIB_VERSION << endl;
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return str.str();
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}
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bool openEMS::SetupBoundaryConditions(TiXmlElement* BC)
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{
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int EC; //error code of tinyxml
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int bounds[6] = {0,0,0,0,0,0}; //default boundary cond. (PEC)
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unsigned int pml_size[6] = {8,8,8,8,8,8}; //default pml size
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string s_bc;
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const char* tmp = BC->Attribute("PML_Grading");
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string pml_gradFunc;
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if (tmp)
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pml_gradFunc = string(tmp);
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string bound_names[] = {"xmin","xmax","ymin","ymax","zmin","zmax"};
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for (int n=0;n<6;++n)
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{
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EC = BC->QueryIntAttribute(bound_names[n].c_str(),&bounds[n]);
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if (EC==TIXML_SUCCESS)
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continue;
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if (EC==TIXML_WRONG_TYPE)
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{
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tmp = BC->Attribute(bound_names[n].c_str());
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if (tmp)
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s_bc = string(tmp);
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if (s_bc=="PEC")
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bounds[n] = 0;
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else if (s_bc=="PMC")
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bounds[n] = 1;
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else if (s_bc=="MUR")
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bounds[n] = 2;
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else if(strncmp(s_bc.c_str(),"PML_=",4)==0)
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{
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bounds[n] = 3;
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pml_size[n] = atoi(s_bc.c_str()+4);
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}
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else
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cerr << "openEMS::SetupBoundaryConditions: Warning, boundary condition for \"" << bound_names[n] << "\" unknown... set to PEC " << endl;
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}
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else
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cerr << "openEMS::SetupBoundaryConditions: Warning, boundary condition for \"" << bound_names[n] << "\" not found... set to PEC " << endl;
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}
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FDTD_Op->SetBoundaryCondition(bounds); //operator only knows about PEC and PMC, everything else is defined by extensions (see below)
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/**************************** create all operator/engine extensions here !!!! **********************************/
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//Mur-ABC, defined as extension to the operator
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double mur_v_ph = 0;
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//read general mur phase velocity
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if (BC->QueryDoubleAttribute("MUR_PhaseVelocity",&mur_v_ph) != TIXML_SUCCESS)
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mur_v_ph = -1;
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string mur_v_ph_names[6] = {"MUR_PhaseVelocity_xmin", "MUR_PhaseVelocity_xmax", "MUR_PhaseVelocity_ymin", "MUR_PhaseVelocity_ymax", "MUR_PhaseVelocity_zmin", "MUR_PhaseVelocity_zmax"};
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for (int n=0;n<6;++n)
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{
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if (bounds[n]==2) //Mur-ABC
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{
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Operator_Ext_Mur_ABC* op_ext_mur = new Operator_Ext_Mur_ABC(FDTD_Op);
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op_ext_mur->SetDirection(n/2,n%2);
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double v_ph = 0;
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//read special mur phase velocity or assign general phase velocity
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if (BC->QueryDoubleAttribute(mur_v_ph_names[n].c_str(),&v_ph) == TIXML_SUCCESS)
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op_ext_mur->SetPhaseVelocity(v_ph);
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else if (mur_v_ph>0)
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op_ext_mur->SetPhaseVelocity(mur_v_ph);
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FDTD_Op->AddExtension(op_ext_mur);
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}
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}
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//create the upml
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Operator_Ext_UPML::Create_UPML(FDTD_Op,bounds,pml_size,pml_gradFunc);
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return true;
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}
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int openEMS::SetupFDTD(const char* file)
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{
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if (file==NULL) return -1;
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Reset();
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cout << "Read openEMS xml file: " << file << " ..." << endl;
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timeval startTime;
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gettimeofday(&startTime,NULL);
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TiXmlDocument doc(file);
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if (!doc.LoadFile())
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{
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cerr << "openEMS: Error File-Loading failed!!! File: " << file << endl;
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exit(-1);
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}
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cout << "Read openEMS Settings..." << endl;
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TiXmlElement* openEMSxml = doc.FirstChildElement("openEMS");
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if (openEMSxml==NULL)
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{
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cerr << "Can't read openEMS ... " << endl;
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exit(-1);
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}
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TiXmlElement* FDTD_Opts = openEMSxml->FirstChildElement("FDTD");
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if (FDTD_Opts==NULL)
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{
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cerr << "Can't read openEMS FDTD Settings... " << endl;
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exit(-1);
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}
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int help=0;
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FDTD_Opts->QueryIntAttribute("NumberOfTimesteps",&help);
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if (help<0)
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NrTS=0;
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else
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NrTS = help;
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help = 0;
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FDTD_Opts->QueryIntAttribute("CylinderCoords",&help);
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if (help==1)
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{
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// cout << "Using a cylinder coordinate FDTD..." << endl;
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CylinderCoords = true;
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}
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FDTD_Opts->QueryDoubleAttribute("endCriteria",&endCrit);
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if (endCrit==0)
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endCrit=1e-6;
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FDTD_Opts->QueryIntAttribute("OverSampling",&m_OverSampling);
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if (m_OverSampling<2)
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m_OverSampling=2;
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double maxTime=0;
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FDTD_Opts->QueryDoubleAttribute("MaxTime",&maxTime);
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TiXmlElement* BC = FDTD_Opts->FirstChildElement("BoundaryCond");
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if (BC==NULL)
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{
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cerr << "Can't read openEMS boundary cond Settings... " << endl;
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exit(-3);
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}
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cout << "Read Geometry..." << endl;
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ContinuousStructure CSX;
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if (CylinderCoords)
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CSX.SetCoordInputType(CYLINDRICAL); //tell CSX to use cylinder-coords
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string EC(CSX.ReadFromXML(openEMSxml));
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if (EC.empty()==false)
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{
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cerr << EC << endl;
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// return(-2);
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}
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if (m_debugCSX)
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CSX.Write2XML("debugCSX.xml");
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//*************** setup operator ************//
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if (CylinderCoords)
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{
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const char* radii = FDTD_Opts->Attribute("MultiGrid");
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if (radii)
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{
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string rad(radii);
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FDTD_Op = Operator_CylinderMultiGrid::New(SplitString2Double(rad,','),m_engine_numThreads);
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}
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else
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FDTD_Op = Operator_Cylinder::New(m_engine_numThreads);
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}
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else if (m_engine == EngineType_SSE)
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{
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FDTD_Op = Operator_sse::New();
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}
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else if (m_engine == EngineType_SSE_Compressed)
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{
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FDTD_Op = Operator_SSE_Compressed::New();
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}
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else if (m_engine == EngineType_Multithreaded)
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{
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FDTD_Op = Operator_Multithread::New(m_engine_numThreads);
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}
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else
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{
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FDTD_Op = Operator::New();
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}
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if (FDTD_Op->SetGeometryCSX(&CSX)==false) return(2);
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SetupBoundaryConditions(BC);
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if (CSX.GetQtyPropertyType(CSProperties::LORENTZMATERIAL)>0)
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FDTD_Op->AddExtension(new Operator_Ext_LorentzMaterial(FDTD_Op));
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double timestep=0;
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FDTD_Opts->QueryDoubleAttribute("TimeStep",×tep);
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if (timestep)
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FDTD_Op->SetTimestep(timestep);
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Operator::DebugFlags debugFlags = Operator::None;
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if (DebugMat)
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debugFlags |= Operator::debugMaterial;
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if (DebugOp)
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debugFlags |= Operator::debugOperator;
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if (m_debugPEC)
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debugFlags |= Operator::debugPEC;
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FDTD_Op->CalcECOperator( debugFlags );
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unsigned int maxTime_TS = (unsigned int)(maxTime/FDTD_Op->GetTimestep());
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if ((maxTime_TS>0) && (maxTime_TS<NrTS))
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NrTS = maxTime_TS;
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if (!FDTD_Op->SetupExcitation( FDTD_Opts->FirstChildElement("Excitation"), NrTS ))
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exit(2);
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timeval OpDoneTime;
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gettimeofday(&OpDoneTime,NULL);
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FDTD_Op->ShowStat();
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FDTD_Op->ShowExtStat();
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cout << "Creation time for operator: " << CalcDiffTime(OpDoneTime,startTime) << " s" << endl;
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if (m_no_simulation) {
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// simulation was disabled (to generate debug output only)
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return 1;
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}
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//create FDTD engine
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FDTD_Eng = FDTD_Op->CreateEngine();
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//*************** setup processing ************//
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cout << "Setting up processing..." << endl;
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unsigned int Nyquist = FDTD_Op->Exc->GetNyquistNum();
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PA = new ProcessingArray(Nyquist);
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double start[3];
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double stop[3];
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vector<CSProperties*> Probes = CSX.GetPropertyByType(CSProperties::PROBEBOX);
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for (size_t i=0;i<Probes.size();++i)
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{
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//only looking for one prim atm
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CSPrimitives* prim = Probes.at(i)->GetPrimitive(0);
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if (prim!=NULL)
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{
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bool acc;
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double bnd[6] = {0,0,0,0,0,0};
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acc = prim->GetBoundBox(bnd,true);
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start[0]= bnd[0];start[1]=bnd[2];start[2]=bnd[4];
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stop[0] = bnd[1];stop[1] =bnd[3];stop[2] =bnd[5];
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CSPropProbeBox* pb = Probes.at(i)->ToProbeBox();
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Processing* proc = NULL;
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if (pb)
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{
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if (pb->GetProbeType()==0)
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{
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ProcessVoltage* procVolt = new ProcessVoltage(FDTD_Op,FDTD_Eng);
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proc=procVolt;
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}
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else if (pb->GetProbeType()==1)
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{
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ProcessCurrent* procCurr = new ProcessCurrent(FDTD_Op,FDTD_Eng);
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proc=procCurr;
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}
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else if (pb->GetProbeType()==2)
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proc = new ProcessEField(FDTD_Op,FDTD_Eng);
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else if (pb->GetProbeType()==3)
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proc = new ProcessHField(FDTD_Op,FDTD_Eng);
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else if ((pb->GetProbeType()==10) || (pb->GetProbeType()==11))
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{
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ProcessModeMatch* pmm = new ProcessModeMatch(FDTD_Op,FDTD_Eng);
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pmm->SetFieldType(pb->GetProbeType()-10);
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pmm->SetModeFunction(0,pb->GetAttributeValue("ModeFunctionX"));
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pmm->SetModeFunction(1,pb->GetAttributeValue("ModeFunctionY"));
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pmm->SetModeFunction(2,pb->GetAttributeValue("ModeFunctionZ"));
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proc = pmm;
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}
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else
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{
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cerr << "openEMS::SetupFDTD: Warning: Probe type " << pb->GetProbeType() << " of property '" << pb->GetName() << "' is unknown..." << endl;
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continue;
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}
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if (CylinderCoords)
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proc->SetMeshType(Processing::CYLINDRICAL_MESH);
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proc->SetProcessInterval(Nyquist/m_OverSampling);
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proc->AddFrequency(pb->GetFDSamples());
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proc->SetName(pb->GetName());
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proc->DefineStartStopCoord(start,stop);
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proc->SetWeight(pb->GetWeighting());
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proc->InitProcess();
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PA->AddProcessing(proc);
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prim->SetPrimitiveUsed(true);
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}
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else
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delete proc;
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}
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}
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vector<CSProperties*> DumpProps = CSX.GetPropertyByType(CSProperties::DUMPBOX);
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for (size_t i=0;i<DumpProps.size();++i)
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{
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ProcessFieldsTD* ProcTD = new ProcessFieldsTD(FDTD_Op,FDTD_Eng);
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ProcTD->SetEnable(Enable_Dumps);
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|
ProcTD->SetProcessInterval(Nyquist/m_OverSampling);
|
|
|
|
//only looking for one prim atm
|
|
CSPrimitives* prim = DumpProps.at(i)->GetPrimitive(0);
|
|
if (prim==NULL)
|
|
delete ProcTD;
|
|
else
|
|
{
|
|
bool acc;
|
|
double bnd[6] = {0,0,0,0,0,0};
|
|
acc = prim->GetBoundBox(bnd,true);
|
|
start[0]= bnd[0];start[1]=bnd[2];start[2]=bnd[4];
|
|
stop[0] = bnd[1];stop[1] =bnd[3];stop[2] =bnd[5];
|
|
CSPropDumpBox* db = DumpProps.at(i)->ToDumpBox();
|
|
if (db)
|
|
{
|
|
ProcTD->SetDumpType((ProcessFields::DumpType)db->GetDumpType());
|
|
ProcTD->SetDumpMode((ProcessFields::DumpMode)db->GetDumpMode());
|
|
ProcTD->SetFileType((ProcessFields::FileType)db->GetFileType());
|
|
if (CylinderCoords)
|
|
ProcTD->SetMeshType(Processing::CYLINDRICAL_MESH);
|
|
for (int n=0;n<3;++n)
|
|
ProcTD->SetSubSampling(db->GetSubSampling(n),n);
|
|
ProcTD->SetFilePattern(db->GetName());
|
|
ProcTD->SetFileName(db->GetName());
|
|
ProcTD->DefineStartStopCoord(start,stop);
|
|
ProcTD->InitProcess();
|
|
PA->AddProcessing(ProcTD);
|
|
prim->SetPrimitiveUsed(true);
|
|
}
|
|
else
|
|
delete ProcTD;
|
|
}
|
|
}
|
|
|
|
CSX.WarnUnusedPrimitves(cerr);
|
|
|
|
// dump all boxes (voltage, current, fields, ...)
|
|
if (m_debugBox)
|
|
{
|
|
PA->DumpBoxes2File("box_dump_");
|
|
}
|
|
|
|
return 0;
|
|
}
|
|
|
|
string FormatTime(int sec)
|
|
{
|
|
stringstream ss;
|
|
if (sec<60)
|
|
{
|
|
ss << setw(9) << sec << "s";
|
|
return ss.str();
|
|
}
|
|
if (sec<3600)
|
|
{
|
|
ss << setw(6) << sec/60 << "m" << setw(2) << setfill('0') << sec%60 << "s";
|
|
return ss.str();
|
|
}
|
|
ss << setw(3) << sec/3600 << "h" << setw(2) << setfill('0') << (sec%3600)/60 << "m" << setw(2) << setfill('0') << sec%60 << "s";
|
|
return ss.str();
|
|
}
|
|
|
|
bool openEMS::CheckAbortCond()
|
|
{
|
|
if (m_Abort) //abort was set externally
|
|
return true;
|
|
|
|
//check whether the file "ABORT" exist in current working directory
|
|
ifstream ifile("ABORT");
|
|
if (ifile)
|
|
{
|
|
ifile.close();
|
|
cerr << "openEMS::CheckAbortCond(): Found file \"ABORT\", aborting simulation..." << endl;
|
|
return true;
|
|
}
|
|
|
|
return false;
|
|
}
|
|
|
|
void openEMS::RunFDTD()
|
|
{
|
|
cout << "Running FDTD engine... this may take a while... grab a cup of coffee?!?" << endl;
|
|
|
|
//special handling of a field processing, needed to realize the end criteria...
|
|
ProcessFields* ProcField = new ProcessFields(FDTD_Op,FDTD_Eng);
|
|
PA->AddProcessing(ProcField);
|
|
double maxE=0,currE=0;
|
|
|
|
//add all timesteps to end-crit field processing with max excite amplitude
|
|
unsigned int maxExcite = FDTD_Op->Exc->GetMaxExcitationTimestep();
|
|
for (unsigned int n=0;n<FDTD_Op->Exc->Volt_Count;++n)
|
|
ProcField->AddStep(FDTD_Op->Exc->Volt_delay[n]+maxExcite);
|
|
|
|
double change=1;
|
|
int prevTS=0,currTS=0;
|
|
double speed = FDTD_Op->GetNumberCells()/1e6;
|
|
double t_diff;
|
|
|
|
timeval currTime;
|
|
gettimeofday(&currTime,NULL);
|
|
timeval startTime = currTime;
|
|
timeval prevTime= currTime;
|
|
|
|
//*************** simulate ************//
|
|
|
|
int step=PA->Process();
|
|
if ((step<0) || (step>(int)NrTS)) step=NrTS;
|
|
while ((FDTD_Eng->GetNumberOfTimesteps()<NrTS) && (change>endCrit) && !CheckAbortCond())
|
|
{
|
|
FDTD_Eng->IterateTS(step);
|
|
step=PA->Process();
|
|
|
|
if (ProcField->CheckTimestep())
|
|
{
|
|
currE = ProcField->CalcTotalEnergy();
|
|
if (currE>maxE)
|
|
maxE=currE;
|
|
}
|
|
|
|
// cout << " do " << step << " steps; current: " << eng.GetNumberOfTimesteps() << endl;
|
|
currTS = FDTD_Eng->GetNumberOfTimesteps();
|
|
if ((step<0) || (step>(int)(NrTS - currTS))) step=NrTS - currTS;
|
|
|
|
gettimeofday(&currTime,NULL);
|
|
|
|
t_diff = CalcDiffTime(currTime,prevTime);
|
|
if (t_diff>4)
|
|
{
|
|
currE = ProcField->CalcTotalEnergy();
|
|
if (currE>maxE)
|
|
maxE=currE;
|
|
cout << "[@" << FormatTime(CalcDiffTime(currTime,startTime)) << "] Timestep: " << setw(12) << currTS << " (" << setw(6) << setprecision(2) << std::fixed << (double)currTS/(double)NrTS*100.0 << "%)" ;
|
|
cout << " || Speed: " << setw(6) << setprecision(1) << std::fixed << speed*(currTS-prevTS)/t_diff << " MC/s (" << setw(4) << setprecision(3) << std::scientific << t_diff/(currTS-prevTS) << " s/TS)" ;
|
|
if (maxE)
|
|
change = currE/maxE;
|
|
cout << " || Energy: ~" << setw(6) << setprecision(2) << std::scientific << currE << " (-" << setw(5) << setprecision(2) << std::fixed << fabs(10.0*log10(change)) << "dB)" << endl;
|
|
prevTime=currTime;
|
|
prevTS=currTS;
|
|
|
|
PA->FlushNext();
|
|
}
|
|
}
|
|
|
|
//*************** postproc ************//
|
|
prevTime = currTime;
|
|
gettimeofday(&currTime,NULL);
|
|
|
|
t_diff = CalcDiffTime(currTime,startTime);
|
|
|
|
cout << "Time for " << FDTD_Eng->GetNumberOfTimesteps() << " iterations with " << FDTD_Op->GetNumberCells() << " cells : " << t_diff << " sec" << endl;
|
|
cout << "Speed: " << speed*(double)FDTD_Eng->GetNumberOfTimesteps()/t_diff << " MCells/s " << endl;
|
|
}
|