applications/staticProps/Hxy.cpp

/*
 * Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
 *
 * The University of Notre Dame grants you ("Licensee") a
 * non-exclusive, royalty free, license to use, modify and
 * redistribute this software in source and binary code form, provided
 * that the following conditions are met:
 *
 * 1. Acknowledgement of the program authors must be made in any
 *    publication of scientific results based in part on use of the
 *    program.  An acceptable form of acknowledgement is citation of
 *    the article in which the program was described (Matthew
 *    A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
 *    J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
 *    Parallel Simulation Engine for Molecular Dynamics,"
 *    J. Comput. Chem. 26, pp. 252-271 (2005))
 *
 * 2. Redistributions of source code must retain the above copyright
 *    notice, this list of conditions and the following disclaimer.
 *
 * 3. Redistributions in binary form must reproduce the above copyright
 *    notice, this list of conditions and the following disclaimer in the
 *    documentation and/or other materials provided with the
 *    distribution.
 *
 * This software is provided "AS IS," without a warranty of any
 * kind. All express or implied conditions, representations and
 * warranties, including any implied warranty of merchantability,
 * fitness for a particular purpose or non-infringement, are hereby
 * excluded.  The University of Notre Dame and its licensors shall not
 * be liable for any damages suffered by licensee as a result of
 * using, modifying or distributing the software or its
 * derivatives. In no event will the University of Notre Dame or its
 * licensors be liable for any lost revenue, profit or data, or for
 * direct, indirect, special, consequential, incidental or punitive
 * damages, however caused and regardless of the theory of liability,
 * arising out of the use of or inability to use software, even if the
 * University of Notre Dame has been advised of the possibility of
 * such damages.
 *
 *
 *  Hxy.cpp
 *  OOPSE-2.0
 *
 *  Created by Xiuquan Sun on 05/09/06.
 *  @author  Xiuquan Sun 
 *  @version $Id: Hxy.cpp,v 1.2 2006-05-16 02:06:37 gezelter Exp $
 *
 */

/* Calculates the undulation spectrum of the lipid membrance. */

#include <algorithm>
#include <fstream>
#include "applications/staticProps/Hxy.hpp"
#include "utils/simError.h"
#include "io/DumpReader.hpp"
#include "primitives/Molecule.hpp"
#include<stdio.h>
#include<string.h>
#include<stdlib.h>
#include<math.h>
#ifndef WITHOUT_FFTW
#include<fftw3.h>
#endif

namespace oopse {
  
  Hxy::Hxy(SimInfo* info, const std::string& filename, const std::string& sele, int nbins_x, int nbins_y, int nrbins)
    : StaticAnalyser(info, filename), selectionScript_(sele),  evaluator_(info), seleMan_(info), nBinsX_(nbins_x), nBinsY_(nbins_y), nbins_(nrbins){

    evaluator_.loadScriptString(sele);
    if (!evaluator_.isDynamic()) {
      seleMan_.setSelectionSet(evaluator_.evaluate());
    }

    gridsample_.resize(nBinsX_*nBinsY_);
    gridZ_.resize(nBinsX_*nBinsY_);

    sum_bin.resize(nbins_);
    avg_bin.resize(nbins_);
    errbin_sum.resize(nbins_);
    errbin.resize(nbins_);
    sum_bin_sq.resize(nbins_);
    avg_bin_sq.resize(nbins_);
    errbin_sum_sq.resize(nbins_);
    errbin_sq.resize(nbins_);

    setOutputName(getPrefix(filename) + ".Hxy");
  }

  void Hxy::process() {
#ifndef WITHOUT_FFTW  

    DumpReader reader(info_, dumpFilename_);    
    int nFrames = reader.getNFrames();
    nProcessed_ = nFrames/step_;
    
    std::vector<double> mag, newmag;
    double lenX_, lenY_;
    double gridX_, gridY_;
    double halfBoxX_, halfBoxY_;
    int binNoX, binNoY;
    double interpsum, value;
    int ninterp, px, py, newp;
    int newx, newy, newindex, index;
    int new_i, new_j, new_index;
    double freq_x, freq_y, zero_freq_x, zero_freq_y, freq;
    double maxfreqx, maxfreqy, maxfreq, dfreq;
    int whichbin;
    int nMolecules;
    
    for (int istep = 0; istep < nFrames; istep += step_) {
      
      reader.readFrame(istep);
      currentSnapshot_ = info_->getSnapshotManager()->getCurrentSnapshot();
      nMolecules = info_->getNGlobalMolecules();

      Mat3x3d hmat = currentSnapshot_->getHmat();

      
      fftw_complex *in, *out;
      fftw_plan p;
      
      in = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) * (nBinsX_*nBinsY_));
      out = (fftw_complex*) fftw_malloc(sizeof(fftw_complex) *(nBinsX_*nBinsY_));
      p =  fftw_plan_dft_2d(nBinsX_, 
                            nBinsY_, 
                            in, out,
                            FFTW_FORWARD, 
                            FFTW_ESTIMATE);
      
      int i, j;   
      
      gridsample_.clear();
      gridZ_.clear();
      sum_bin.clear();
      avg_bin.clear();
      errbin_sum.clear();
      errbin.clear();
      sum_bin_sq.clear();
      avg_bin_sq.clear();
      errbin_sum_sq.clear();
      errbin_sq.clear();
      
      mag.resize(nBinsX_*nBinsY_);
      newmag.resize(nBinsX_*nBinsY_);     
      mag.clear();
      newmag.clear();
      
      StuntDouble* sd;
      
      lenX_ = hmat(0,0);
      lenY_ = hmat(1,1);
      
      gridX_ = lenX_ /(nBinsX_);
      gridY_ = lenY_ /(nBinsY_);
      
      double halfBoxX_ = lenX_ / 2.0;      
      double halfBoxY_ = lenY_ / 2.0;      
      
      if (evaluator_.isDynamic()) {
        seleMan_.setSelectionSet(evaluator_.evaluate());
      }
      
      //wrap the stuntdoubles into a cell     
      for (sd = seleMan_.beginSelected(i); sd != NULL; sd = seleMan_.nextSelected(i)) {
        Vector3d pos = sd->getPos();
        currentSnapshot_->wrapVector(pos);
        sd->setPos(pos);
      }
      
      //determine which atom belongs to which grid
      for (sd = seleMan_.beginSelected(i); sd != NULL; sd = seleMan_.nextSelected(i)) {
        Vector3d pos = sd->getPos();
        //int binNo = (pos.z() /deltaR_) - 1;
        int binNoX = (pos.x() + halfBoxX_) /gridX_; 
        int binNoY = (pos.y() + halfBoxY_) /gridY_;
        //std::cout << "pos.z = " << pos.z() << " halfBoxZ_ = " << halfBoxZ_ << " deltaR_ = "  << deltaR_ << " binNo = " << binNo << "\n";
        gridZ_[binNoX*nBinsY_+binNoY] += pos.z();
        gridsample_[binNoX*nBinsY_+binNoY]++;
      }
      
      // FFT stuff depends on nx and ny, so delay allocation until we have
      // that information
      
      for (i=0; i< nBinsX_; i++) {
        for(j=0; j< nBinsY_; j++) {
          newindex = i*nBinsY_ + j;
          mag[newindex] = 0.0;
          newmag[newindex] = 0.0;
        }
      }
      
      for(i = 0; i < nBinsX_; i++){
        for(j = 0; j < nBinsY_; j++){
          newindex = i * nBinsY_ + j;
          if(gridsample_[newindex] > 0){
            gridZ_[newindex] = gridZ_[newindex] / (double)gridsample_[newindex];
          }
        }
      }
      
      for (i=0; i< nBinsX_; i++) {
        for(j=0; j< nBinsY_; j++) {
          newindex = i*nBinsY_ + j;
          if (gridsample_[newindex] == 0) {
            // interpolate from surrounding points:
            
            interpsum = 0.0;
            ninterp = 0;
            
            //point1 = bottom;
            
            px = i;
            py = j - 1;
            newp = px*nBinsY_ + py;
            if ((py >= 0) && (gridsample_[newp] > 0)) {
              interpsum += gridZ_[newp];
              ninterp++;
            } 
            
            //point2 = top;
            
            px = i;
            py = j + 1;
            newp = px*nBinsY_ + py;
            if ((py < nBinsY_) && (gridsample_[newp] > 0)) {
              interpsum += gridZ_[newp];
              ninterp++;
            } 
            
            //point3 = left;
            
            px = i - 1;
            py = j;
            newp = px*nBinsY_ + py;
            if ((px >= 0) && (gridsample_[newp] > 0)) {
              interpsum += gridZ_[newp];
              ninterp++;
            }
            
            //point4 = right;
            
            px = i + 1;
            py = j;
            newp = px*nBinsY_ + py;
            if ( (px < nBinsX_ ) && ( gridsample_[newp] > 0 )) { 
              interpsum += gridZ_[newp];
              ninterp++;
            } 
        
            value = interpsum / (double)ninterp;
            
            gridZ_[newindex] = value;
          }
        }
      }
      
      for (i=0; i < nBinsX_; i++) {
        for (j=0; j < nBinsY_; j++) {
          newindex = i*nBinsY_ + j;
          
          c_re(in[newindex]) = gridZ_[newindex];
          c_im(in[newindex]) = 0.0;
        } 
      }
      
      fftw_execute(p); 
      
      for (i=0; i< nBinsX_; i++) {
        for(j=0; j< nBinsY_; j++) {
          newindex = i*nBinsY_ + j;
          mag[newindex] = pow(c_re(out[newindex]),2) + pow(c_im(out[newindex]),2);
        }
      }
      
      fftw_destroy_plan(p);
      fftw_free(out);
      fftw_free(in);

      for (i=0; i< (nBinsX_/2); i++) {
        for(j=0; j< (nBinsY_/2); j++) {
          index = i*nBinsY_ + j;
          new_i = i + (nBinsX_/2);
          new_j = j + (nBinsY_/2);
          new_index = new_i*nBinsY_ + new_j;
          newmag[new_index] = mag[index];
        }
      }
      
      for (i=(nBinsX_/2); i< nBinsX_; i++) {
        for(j=0; j< (nBinsY_/2); j++) {
          index = i*nBinsY_ + j;
          new_i = i - (nBinsX_/2);
          new_j = j + (nBinsY_/2);
          new_index = new_i*nBinsY_ + new_j;
          newmag[new_index] = mag[index];
        }
      }
      
      for (i=0; i< (nBinsX_/2); i++) {
        for(j=(nBinsY_/2); j< nBinsY_; j++) {
          index = i*nBinsY_ + j;
          new_i = i + (nBinsX_/2);
          new_j = j - (nBinsY_/2);
          new_index = new_i*nBinsY_ + new_j;
          newmag[new_index] = mag[index];
        }
      }
      
      for (i=(nBinsX_/2); i< nBinsX_; i++) {
        for(j=(nBinsY_/2); j< nBinsY_; j++) {
          index = i*nBinsY_ + j;
          new_i = i - (nBinsX_/2);
          new_j = j - (nBinsY_/2);
          new_index = new_i*nBinsY_ + new_j;
          newmag[new_index] = mag[index];
        }
      }
    
      maxfreqx = 1.0 / gridX_;
      maxfreqy = 1.0 / gridY_;
      
      //  printf("%lf\t%lf\t%lf\t%lf\n", dx, dy, maxfreqx, maxfreqy);
      
      maxfreq = sqrt(maxfreqx*maxfreqx + maxfreqy*maxfreqy);
      dfreq = maxfreq/(double)(nbins_-1);
    
      //printf("%lf\n", dfreq);
      
      zero_freq_x = nBinsX_/2; 
      zero_freq_y = nBinsY_/2; 
      
      for (i=0; i< nBinsX_; i++) {
        for(j=0; j< nBinsY_; j++) {
          
          freq_x = (double)(i - zero_freq_x)*maxfreqx*2 / nBinsX_;
          freq_y = (double)(j - zero_freq_y)*maxfreqy*2 / nBinsY_;
          
          freq = sqrt(freq_x*freq_x + freq_y*freq_y);
          
          whichbin = (int) (freq / dfreq);
          newindex = i*nBinsY_ + j;
          //    printf("%d %d %lf %lf\n", whichbin, newindex, freq, dfreq);
          bin[whichbin][istep] += newmag[newindex];
          samples[whichbin][istep]++;
        }
      }
      
      for ( i = 0; i < nbins_; i++) {
        if ( samples[i][istep] > 0) {
          bin[i][istep] = 4.0 * sqrt(bin[i][istep] / (double)samples[i][istep]) / (double)nMolecules;
        }
      }    
      
    }
  
    for (int i = 0; i < nbins_; i++) {
      for (int j = 0; j < nFrames; j++) {
        sum_bin[i] += bin[i][j];
        sum_bin_sq[i] += bin[i][j] * bin[i][j];
      }
      avg_bin[i] = sum_bin[i] / (double)nFrames;
      avg_bin_sq[i] = sum_bin_sq[i] / (double)nFrames;
      for (int j = 0; j < nFrames; j++) {
        errbin_sum[i] += pow((bin[i][j] - avg_bin[i]), 2);
        errbin_sum_sq[i] += pow((bin[i][j] * bin[i][j] - avg_bin_sq[i]), 2);
      }
      errbin[i] = sqrt( errbin_sum[i] / (double)nFrames );
      errbin_sq[i] = sqrt( errbin_sum_sq[i] / (double)nFrames );
    }
    
    printSpectrum();
#else
    sprintf(painCave.errMsg, "Hxy: FFTW support was not compiled in!\n");
    painCave.isFatal = 1;
    simError();  

#endif

}
    
  void Hxy::printSpectrum() {
    std::ofstream rdfStream(outputFilename_.c_str());
    if (rdfStream.is_open()) {
      
      for (int i = 0; i < nbins_; i++) {
        if ( avg_bin[i] > 0 ){
          rdfStream << i*dfreq << "\t"
                    <<pow(avg_bin[i], 2)<<"\t"
                    <<errbin_sq[i]<<"\t"
                    <<avg_bin[i]<<"\t"
                    <<errbin[i]<<"\n";
        }
      }
    } else {
      
      sprintf(painCave.errMsg, "Hxy: unable to open %s\n", outputFilename_.c_str());
      painCave.isFatal = 1;
      simError();  
    }
    
    rdfStream.close();
  }
  
}
Revision:	956
Committed:	Tue May 16 02:06:37 2006 UTC (19 years, 5 months ago) by gezelter
File size:	11632 byte(s)
Log Message:	* empty log message *
#	Content
1	/*
2	* Copyright (c) 2005 The University of Notre Dame. All Rights Reserved.
3	*
4	* The University of Notre Dame grants you ("Licensee") a
5	* non-exclusive, royalty free, license to use, modify and
6	* redistribute this software in source and binary code form, provided
7	* that the following conditions are met:
8	*
9	* 1. Acknowledgement of the program authors must be made in any
10	* publication of scientific results based in part on use of the
11	* program. An acceptable form of acknowledgement is citation of
12	* the article in which the program was described (Matthew
13	* A. Meineke, Charles F. Vardeman II, Teng Lin, Christopher
14	* J. Fennell and J. Daniel Gezelter, "OOPSE: An Object-Oriented
15	* Parallel Simulation Engine for Molecular Dynamics,"
16	* J. Comput. Chem. 26, pp. 252-271 (2005))
17	*
18	* 2. Redistributions of source code must retain the above copyright
19	* notice, this list of conditions and the following disclaimer.
20	*
21	* 3. Redistributions in binary form must reproduce the above copyright
22	* notice, this list of conditions and the following disclaimer in the
23	* documentation and/or other materials provided with the
24	* distribution.
25	*
26	* This software is provided "AS IS," without a warranty of any
27	* kind. All express or implied conditions, representations and
28	* warranties, including any implied warranty of merchantability,
29	* fitness for a particular purpose or non-infringement, are hereby
30	* excluded. The University of Notre Dame and its licensors shall not
31	* be liable for any damages suffered by licensee as a result of
32	* using, modifying or distributing the software or its
33	* derivatives. In no event will the University of Notre Dame or its
34	* licensors be liable for any lost revenue, profit or data, or for
35	* direct, indirect, special, consequential, incidental or punitive
36	* damages, however caused and regardless of the theory of liability,
37	* arising out of the use of or inability to use software, even if the
38	* University of Notre Dame has been advised of the possibility of
39	* such damages.
40	*
41	*
42	* Hxy.cpp
43	* OOPSE-2.0
44	*
45	* Created by Xiuquan Sun on 05/09/06.
46	* @author Xiuquan Sun
47	* @version $Id: Hxy.cpp,v 1.2 2006-05-16 02:06:37 gezelter Exp $
48	*
49	*/
50
51	/* Calculates the undulation spectrum of the lipid membrance. */
52
53	#include <algorithm>
54	#include <fstream>
55	#include "applications/staticProps/Hxy.hpp"
56	#include "utils/simError.h"
57	#include "io/DumpReader.hpp"
58	#include "primitives/Molecule.hpp"
59	#include<stdio.h>
60	#include<string.h>
61	#include<stdlib.h>
62	#include<math.h>
63	#ifndef WITHOUT_FFTW
64	#include<fftw3.h>
65	#endif
66
67	namespace oopse {
68
69	Hxy::Hxy(SimInfo* info, const std::string& filename, const std::string& sele, int nbins_x, int nbins_y, int nrbins)
70	: StaticAnalyser(info, filename), selectionScript_(sele), evaluator_(info), seleMan_(info), nBinsX_(nbins_x), nBinsY_(nbins_y), nbins_(nrbins){
71
72	evaluator_.loadScriptString(sele);
73	if (!evaluator_.isDynamic()) {
74	seleMan_.setSelectionSet(evaluator_.evaluate());
75	}
76
77	gridsample_.resize(nBinsX_*nBinsY_);
78	gridZ_.resize(nBinsX_*nBinsY_);
79
80	sum_bin.resize(nbins_);
81	avg_bin.resize(nbins_);
82	errbin_sum.resize(nbins_);
83	errbin.resize(nbins_);
84	sum_bin_sq.resize(nbins_);
85	avg_bin_sq.resize(nbins_);
86	errbin_sum_sq.resize(nbins_);
87	errbin_sq.resize(nbins_);
88
89	setOutputName(getPrefix(filename) + ".Hxy");
90	}
91
92	void Hxy::process() {
93	#ifndef WITHOUT_FFTW
94
95	DumpReader reader(info_, dumpFilename_);
96	int nFrames = reader.getNFrames();
97	nProcessed_ = nFrames/step_;
98
99	std::vector<double> mag, newmag;
100	double lenX_, lenY_;
101	double gridX_, gridY_;
102	double halfBoxX_, halfBoxY_;
103	int binNoX, binNoY;
104	double interpsum, value;
105	int ninterp, px, py, newp;
106	int newx, newy, newindex, index;
107	int new_i, new_j, new_index;
108	double freq_x, freq_y, zero_freq_x, zero_freq_y, freq;
109	double maxfreqx, maxfreqy, maxfreq, dfreq;
110	int whichbin;
111	int nMolecules;
112
113	for (int istep = 0; istep < nFrames; istep += step_) {
114
115	reader.readFrame(istep);
116	currentSnapshot_ = info_->getSnapshotManager()->getCurrentSnapshot();
117	nMolecules = info_->getNGlobalMolecules();
118
119	Mat3x3d hmat = currentSnapshot_->getHmat();
120
121
122	fftw_complex in, out;
123	fftw_plan p;
124
125	in = (fftw_complex) fftw_malloc(sizeof(fftw_complex) (nBinsX_*nBinsY_));
126	out = (fftw_complex) fftw_malloc(sizeof(fftw_complex) (nBinsX_*nBinsY_));
127	p = fftw_plan_dft_2d(nBinsX_,
128	nBinsY_,
129	in, out,
130	FFTW_FORWARD,
131	FFTW_ESTIMATE);
132
133	int i, j;
134
135	gridsample_.clear();
136	gridZ_.clear();
137	sum_bin.clear();
138	avg_bin.clear();
139	errbin_sum.clear();
140	errbin.clear();
141	sum_bin_sq.clear();
142	avg_bin_sq.clear();
143	errbin_sum_sq.clear();
144	errbin_sq.clear();
145
146	mag.resize(nBinsX_*nBinsY_);
147	newmag.resize(nBinsX_*nBinsY_);
148	mag.clear();
149	newmag.clear();
150
151	StuntDouble* sd;
152
153	lenX_ = hmat(0,0);
154	lenY_ = hmat(1,1);
155
156	gridX_ = lenX_ /(nBinsX_);
157	gridY_ = lenY_ /(nBinsY_);
158
159	double halfBoxX_ = lenX_ / 2.0;
160	double halfBoxY_ = lenY_ / 2.0;
161
162	if (evaluator_.isDynamic()) {
163	seleMan_.setSelectionSet(evaluator_.evaluate());
164	}
165
166	//wrap the stuntdoubles into a cell
167	for (sd = seleMan_.beginSelected(i); sd != NULL; sd = seleMan_.nextSelected(i)) {
168	Vector3d pos = sd->getPos();
169	currentSnapshot_->wrapVector(pos);
170	sd->setPos(pos);
171	}
172
173	//determine which atom belongs to which grid
174	for (sd = seleMan_.beginSelected(i); sd != NULL; sd = seleMan_.nextSelected(i)) {
175	Vector3d pos = sd->getPos();
176	//int binNo = (pos.z() /deltaR_) - 1;
177	int binNoX = (pos.x() + halfBoxX_) /gridX_;
178	int binNoY = (pos.y() + halfBoxY_) /gridY_;
179	//std::cout << "pos.z = " << pos.z() << " halfBoxZ_ = " << halfBoxZ_ << " deltaR_ = " << deltaR_ << " binNo = " << binNo << "\n";
180	gridZ_[binNoX*nBinsY_+binNoY] += pos.z();
181	gridsample_[binNoX*nBinsY_+binNoY]++;
182	}
183
184	// FFT stuff depends on nx and ny, so delay allocation until we have
185	// that information
186
187	for (i=0; i< nBinsX_; i++) {
188	for(j=0; j< nBinsY_; j++) {
189	newindex = i*nBinsY_ + j;
190	mag[newindex] = 0.0;
191	newmag[newindex] = 0.0;
192	}
193	}
194
195	for(i = 0; i < nBinsX_; i++){
196	for(j = 0; j < nBinsY_; j++){
197	newindex = i * nBinsY_ + j;
198	if(gridsample_[newindex] > 0){
199	gridZ_[newindex] = gridZ_[newindex] / (double)gridsample_[newindex];
200	}
201	}
202	}
203
204	for (i=0; i< nBinsX_; i++) {
205	for(j=0; j< nBinsY_; j++) {
206	newindex = i*nBinsY_ + j;
207	if (gridsample_[newindex] == 0) {
208	// interpolate from surrounding points:
209
210	interpsum = 0.0;
211	ninterp = 0;
212
213	//point1 = bottom;
214
215	px = i;
216	py = j - 1;
217	newp = px*nBinsY_ + py;
218	if ((py >= 0) && (gridsample_[newp] > 0)) {
219	interpsum += gridZ_[newp];
220	ninterp++;
221	}
222
223	//point2 = top;
224
225	px = i;
226	py = j + 1;
227	newp = px*nBinsY_ + py;
228	if ((py < nBinsY_) && (gridsample_[newp] > 0)) {
229	interpsum += gridZ_[newp];
230	ninterp++;
231	}
232
233	//point3 = left;
234
235	px = i - 1;
236	py = j;
237	newp = px*nBinsY_ + py;
238	if ((px >= 0) && (gridsample_[newp] > 0)) {
239	interpsum += gridZ_[newp];
240	ninterp++;
241	}
242
243	//point4 = right;
244
245	px = i + 1;
246	py = j;
247	newp = px*nBinsY_ + py;
248	if ( (px < nBinsX_ ) && ( gridsample_[newp] > 0 )) {
249	interpsum += gridZ_[newp];
250	ninterp++;
251	}
252
253	value = interpsum / (double)ninterp;
254
255	gridZ_[newindex] = value;
256	}
257	}
258	}
259
260	for (i=0; i < nBinsX_; i++) {
261	for (j=0; j < nBinsY_; j++) {
262	newindex = i*nBinsY_ + j;
263
264	c_re(in[newindex]) = gridZ_[newindex];
265	c_im(in[newindex]) = 0.0;
266	}
267	}
268
269	fftw_execute(p);
270
271	for (i=0; i< nBinsX_; i++) {
272	for(j=0; j< nBinsY_; j++) {
273	newindex = i*nBinsY_ + j;
274	mag[newindex] = pow(c_re(out[newindex]),2) + pow(c_im(out[newindex]),2);
275	}
276	}
277
278	fftw_destroy_plan(p);
279	fftw_free(out);
280	fftw_free(in);
281
282	for (i=0; i< (nBinsX_/2); i++) {
283	for(j=0; j< (nBinsY_/2); j++) {
284	index = i*nBinsY_ + j;
285	new_i = i + (nBinsX_/2);
286	new_j = j + (nBinsY_/2);
287	new_index = new_i*nBinsY_ + new_j;
288	newmag[new_index] = mag[index];
289	}
290	}
291
292	for (i=(nBinsX_/2); i< nBinsX_; i++) {
293	for(j=0; j< (nBinsY_/2); j++) {
294	index = i*nBinsY_ + j;
295	new_i = i - (nBinsX_/2);
296	new_j = j + (nBinsY_/2);
297	new_index = new_i*nBinsY_ + new_j;
298	newmag[new_index] = mag[index];
299	}
300	}
301
302	for (i=0; i< (nBinsX_/2); i++) {
303	for(j=(nBinsY_/2); j< nBinsY_; j++) {
304	index = i*nBinsY_ + j;
305	new_i = i + (nBinsX_/2);
306	new_j = j - (nBinsY_/2);
307	new_index = new_i*nBinsY_ + new_j;
308	newmag[new_index] = mag[index];
309	}
310	}
311
312	for (i=(nBinsX_/2); i< nBinsX_; i++) {
313	for(j=(nBinsY_/2); j< nBinsY_; j++) {
314	index = i*nBinsY_ + j;
315	new_i = i - (nBinsX_/2);
316	new_j = j - (nBinsY_/2);
317	new_index = new_i*nBinsY_ + new_j;
318	newmag[new_index] = mag[index];
319	}
320	}
321
322	maxfreqx = 1.0 / gridX_;
323	maxfreqy = 1.0 / gridY_;
324
325	// printf("%lf\t%lf\t%lf\t%lf\n", dx, dy, maxfreqx, maxfreqy);
326
327	maxfreq = sqrt(maxfreqxmaxfreqx + maxfreqymaxfreqy);
328	dfreq = maxfreq/(double)(nbins_-1);
329
330	//printf("%lf\n", dfreq);
331
332	zero_freq_x = nBinsX_/2;
333	zero_freq_y = nBinsY_/2;
334
335	for (i=0; i< nBinsX_; i++) {
336	for(j=0; j< nBinsY_; j++) {
337
338	freq_x = (double)(i - zero_freq_x)maxfreqx2 / nBinsX_;
339	freq_y = (double)(j - zero_freq_y)maxfreqy2 / nBinsY_;
340
341	freq = sqrt(freq_xfreq_x + freq_yfreq_y);
342
343	whichbin = (int) (freq / dfreq);
344	newindex = i*nBinsY_ + j;
345	// printf("%d %d %lf %lf\n", whichbin, newindex, freq, dfreq);
346	bin[whichbin][istep] += newmag[newindex];
347	samples[whichbin][istep]++;
348	}
349	}
350
351	for ( i = 0; i < nbins_; i++) {
352	if ( samples[i][istep] > 0) {
353	bin[i][istep] = 4.0 * sqrt(bin[i][istep] / (double)samples[i][istep]) / (double)nMolecules;
354	}
355	}
356
357	}
358
359	for (int i = 0; i < nbins_; i++) {
360	for (int j = 0; j < nFrames; j++) {
361	sum_bin[i] += bin[i][j];
362	sum_bin_sq[i] += bin[i][j] * bin[i][j];
363	}
364	avg_bin[i] = sum_bin[i] / (double)nFrames;
365	avg_bin_sq[i] = sum_bin_sq[i] / (double)nFrames;
366	for (int j = 0; j < nFrames; j++) {
367	errbin_sum[i] += pow((bin[i][j] - avg_bin[i]), 2);
368	errbin_sum_sq[i] += pow((bin[i][j] * bin[i][j] - avg_bin_sq[i]), 2);
369	}
370	errbin[i] = sqrt( errbin_sum[i] / (double)nFrames );
371	errbin_sq[i] = sqrt( errbin_sum_sq[i] / (double)nFrames );
372	}
373
374	printSpectrum();
375	#else
376	sprintf(painCave.errMsg, "Hxy: FFTW support was not compiled in!\n");
377	painCave.isFatal = 1;
378	simError();
379
380	#endif
381
382	}
383
384	void Hxy::printSpectrum() {
385	std::ofstream rdfStream(outputFilename_.c_str());
386	if (rdfStream.is_open()) {
387
388	for (int i = 0; i < nbins_; i++) {
389	if ( avg_bin[i] > 0 ){
390	rdfStream << i*dfreq << "\t"
391	<<pow(avg_bin[i], 2)<<"\t"
392	<<errbin_sq[i]<<"\t"
393	<<avg_bin[i]<<"\t"
394	<<errbin[i]<<"\n";
395	}
396	}
397	} else {
398
399	sprintf(painCave.errMsg, "Hxy: unable to open %s\n", outputFilename_.c_str());
400	painCave.isFatal = 1;
401	simError();
402	}
403
404	rdfStream.close();
405	}
406
407	}