/* * Copyright (C) 2010 Thorsten Liebig (Thorsten.Liebig@gmx.de) * * This program is free software: you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation, either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program. If not, see . */ #include "tools/global.h" #include "tools/useful.h" #include "Common/operator_base.h" #include #include "processing.h" #include Processing::Processing(Engine_Interface_Base* eng_if) { m_Eng_Interface = NULL; SetEngineInterface(eng_if); Enabled = true; m_PS_pos = 0; SetPrecision(12); ProcessInterval=0; m_FD_SampleCount=0; m_FD_Interval=0; m_weight=1; m_Flush = false; m_dualMesh = false; m_dualTime = false; m_SnapMethod = 0; m_Mesh_Type = CARTESIAN_MESH; for (int n=0;n<3;++n) { start[n]=0; stop[n]=0; } } Processing::~Processing() { SetEngineInterface(NULL); file.close(); } void Processing::Reset() { m_PS_pos=0; } void Processing::SetEngineInterface(Engine_Interface_Base* eng_if) { delete m_Eng_Interface; m_Eng_Interface = eng_if; if (m_Eng_Interface) Op=m_Eng_Interface->GetOperator(); else Op=NULL; } bool Processing::CheckTimestep() { if (m_ProcessSteps.size()>m_PS_pos) { if (m_ProcessSteps.at(m_PS_pos)==m_Eng_Interface->GetNumberOfTimesteps()) { ++m_PS_pos; return true; } } if (ProcessInterval) { if (m_Eng_Interface->GetNumberOfTimesteps()%ProcessInterval==0) return true; } if (m_FD_Interval) { if (m_Eng_Interface->GetNumberOfTimesteps()%m_FD_Interval==0) return true; } return false; } int Processing::GetNextInterval() const { if (Enabled==false) return -1; int next=INT_MAX; if (m_ProcessSteps.size()>m_PS_pos) { next = (int)m_ProcessSteps.at(m_PS_pos)-(int)m_Eng_Interface->GetNumberOfTimesteps(); } if (ProcessInterval!=0) { int next_Interval = (int)ProcessInterval - (int)m_Eng_Interface->GetNumberOfTimesteps()%ProcessInterval; if (next_IntervalGetNumberOfTimesteps()%m_FD_Interval; if (next_Interval steps) { for (size_t n=0; nGetTimestep()); if (nyquistTS == 0) { cerr << "Processing::AddFrequency: Requested frequency " << freq << " is too high for the current timestep used... skipping..." << endl; return; } else if (nyquistTSGetNumberOfNyquistTimesteps()) { cerr << "Processing::AddFrequency: Warning: Requested frequency " << freq << " is higher than maximum excited frequency..." << endl; } if (m_FD_Interval==0) m_FD_Interval = Op->GetNumberOfNyquistTimesteps(); if (m_FD_Interval>nyquistTS) m_FD_Interval = nyquistTS; m_FD_Samples.push_back(freq); } void Processing::AddFrequency(vector *freqs) { for (size_t n=0; nsize(); ++n) { AddFrequency(freqs->at(n)); } } void Processing::DefineStartStopCoord(double* dstart, double* dstop) { m_Dimension = Op->SnapBox2Mesh(dstart,dstop,start,stop,m_dualMesh,m_SnapMethod, m_start_inside, m_stop_inside); if (m_Dimension<0) { cerr << "Processing::DefineStartStopCoord: Warning in " << m_Name << " (" << GetProcessingName() << ") : Box is outside the field domain!! Disabling" << endl; Enabled = false; return; } } void Processing::ShowSnappedCoords() { cerr << m_Name << ": snapped coords: (" << Op->GetDiscLine( 0, start[0], m_dualMesh ) << "," << Op->GetDiscLine( 1, start[1], m_dualMesh ) << "," << Op->GetDiscLine( 2, start[2], m_dualMesh ) << ") -> (" << Op->GetDiscLine( 0, stop[0], m_dualMesh ) << ","<< Op->GetDiscLine( 1, stop[1], m_dualMesh ) << "," << Op->GetDiscLine( 2, stop[2], m_dualMesh ) << ")"; cerr << " [" << start[0] << "," << start[1] << "," << start[2] << "] -> [" << stop[0] << "," << stop[1] << "," << stop[2] << "]" << endl; } void Processing::OpenFile( string outfile ) { if (file.is_open()) file.close(); file.open( outfile.c_str() ); if (!file.is_open()) cerr << "Can't open file: " << outfile << endl; m_filename = outfile; } void Processing::PostProcess() { FlushData(); } void Processing::DumpBox2File( string vtkfilenameprefix, bool dualMesh ) const { string vtkfilename = vtkfilenameprefix + m_filename + ".vtk"; ofstream file( vtkfilename.c_str() ); if (!file.is_open()) { cerr << "Processing::DumpBoxes2File(): Can't open file: " << vtkfilename << endl; return; } // normalize coordinates double s1[3], s2[3]; for (int i=0; i<3; i++) { s1[i] = min(Op->GetDiscLine(i,start[i],dualMesh),Op->GetDiscLine(i,stop[i],dualMesh)); s2[i] = max(Op->GetDiscLine(i,start[i],dualMesh),Op->GetDiscLine(i,stop[i],dualMesh)); } // fix degenerate box/plane -> line (paraview display problem) if (((s1[0] == s2[0]) && (s1[1] == s2[1])) || ((s1[0] == s2[0]) && (s1[2] == s2[2])) || ((s1[2] == s2[2]) && (s1[1] == s2[1]))) { // line are not displayed correctly -> enlarge for (int i=0; i<3; i++) { double delta = min( Op->GetEdgeLength( i, start,dualMesh ), Op->GetEdgeLength( i, stop,dualMesh ) ) / Op->GetGridDelta() / 4.0; s1[i] -= delta; s2[i] += delta; } } // rescale coordinates #ifndef OUTPUT_IN_DRAWINGUNITS double scaling = Op->GetGridDelta(); for (int i=0; i<3; i++) { s1[i] *= scaling; s2[i] *= scaling; } #endif file << "# vtk DataFile Version 2.0" << endl; file << "" << endl; file << "ASCII" << endl; file << "DATASET POLYDATA" << endl; file << "POINTS 8 float" << endl; file << s1[0] << " " << s1[1] << " " << s1[2] << endl; file << s2[0] << " " << s1[1] << " " << s1[2] << endl; file << s2[0] << " " << s2[1] << " " << s1[2] << endl; file << s1[0] << " " << s2[1] << " " << s1[2] << endl; file << s1[0] << " " << s1[1] << " " << s2[2] << endl; file << s2[0] << " " << s1[1] << " " << s2[2] << endl; file << s2[0] << " " << s2[1] << " " << s2[2] << endl; file << s1[0] << " " << s2[1] << " " << s2[2] << endl; file << "POLYGONS 6 30" << endl; file << "4 0 1 2 3" << endl; file << "4 4 5 6 7" << endl; file << "4 7 6 2 3" << endl; file << "4 4 5 1 0" << endl; file << "4 0 4 7 3" << endl; file << "4 5 6 2 1" << endl; file.close(); } void ProcessingArray::AddProcessing(Processing* proc) { ProcessArray.push_back(proc); } void ProcessingArray::InitAll() { for (size_t i=0; iInitProcess(); } } void ProcessingArray::FlushNext() { for (size_t i=0; iFlushNext(); } } void ProcessingArray::Reset() { for (size_t i=0; iReset(); } } void ProcessingArray::DeleteAll() { for (size_t i=0; iPreProcess(); } int ProcessingArray::Process() { int nextProcess=maxInterval; //this could be done nicely in parallel?? for (size_t i=0; iProcess(); if ((step>0) && (stepPostProcess(); } void ProcessingArray::DumpBoxes2File( string vtkfilenameprefix ) const { for (size_t i=0; iDumpBox2File( vtkfilenameprefix ); }