src/io/DumpWriter.cpp

#define _LARGEFILE_SOURCE64
#define _FILE_OFFSET_BITS 64

#include <string.h>
#include <iostream>
#include <fstream>
#include <algorithm>
#include <utility>

#ifdef IS_MPI
#include <mpi.h>
#include "brains/mpiSimulation.hpp"

namespace dWrite{
  void DieDieDie( void );
}

using namespace dWrite;
#endif //is_mpi

#include "io/ReadWrite.hpp"
#include "utils/simError.h"

DumpWriter::DumpWriter( SimInfo* the_entry_plug ){

  entry_plug = the_entry_plug;

#ifdef IS_MPI
  if(worldRank == 0 ){
#endif // is_mpi

    dumpFile.open(entry_plug->sampleName.c_str(), ios::out | ios::trunc );

    if( !dumpFile ){

      sprintf( painCave.errMsg,
               "Could not open \"%s\" for dump output.\n",
               entry_plug->sampleName.c_str());
      painCave.isFatal = 1;
      simError();
    }

#ifdef IS_MPI
  }

  //sort the local atoms by global index
  sortByGlobalIndex();
  
  sprintf( checkPointMsg,
           "Sucessfully opened output file for dumping.\n");
  MPIcheckPoint();
#endif // is_mpi
}

DumpWriter::~DumpWriter( ){

#ifdef IS_MPI
  if(worldRank == 0 ){
#endif // is_mpi

    dumpFile.close();

#ifdef IS_MPI
  }
#endif // is_mpi
}

#ifdef IS_MPI

/**
 * A hook function to load balancing
 */

void DumpWriter::update(){
  sortByGlobalIndex();          
}
  
/**
 * Auxiliary sorting function
 */
 
bool indexSortingCriterion(const pair<int, int>& p1, const pair<int, int>& p2){
  return p1.second < p2.second;
}

/**
 * Sorting the local index by global index
 */
 
void DumpWriter::sortByGlobalIndex(){
  Molecule* mols = entry_plug->molecules;  
  indexArray.clear();
  
  for(int i = 0; i < entry_plug->n_mol;i++) 
    indexArray.push_back(make_pair(i, mols[i].getGlobalIndex()));
  
  sort(indexArray.begin(), indexArray.end(), indexSortingCriterion);    
}

#endif

void DumpWriter::writeDump(double currentTime){

  ofstream finalOut;
  vector<ofstream*> fileStreams;

#ifdef IS_MPI
  if(worldRank == 0 ){
#endif    
    finalOut.open( entry_plug->finalName.c_str(), ios::out | ios::trunc );
    if( !finalOut ){
      sprintf( painCave.errMsg,
               "Could not open \"%s\" for final dump output.\n",
               entry_plug->finalName.c_str() );
      painCave.isFatal = 1;
      simError();
    }
#ifdef IS_MPI
  }
#endif // is_mpi

  fileStreams.push_back(&finalOut); 
  fileStreams.push_back(&dumpFile);

  writeFrame(fileStreams, currentTime);

#ifdef IS_MPI
  finalOut.close();
#endif
        
}

void DumpWriter::writeFinal(double currentTime){

  ofstream finalOut;
  vector<ofstream*> fileStreams;

#ifdef IS_MPI
  if(worldRank == 0 ){
#endif // is_mpi

    finalOut.open( entry_plug->finalName.c_str(), ios::out | ios::trunc );

    if( !finalOut ){
      sprintf( painCave.errMsg,
               "Could not open \"%s\" for final dump output.\n",
               entry_plug->finalName.c_str() );
      painCave.isFatal = 1;
      simError();
    }

#ifdef IS_MPI
  }
#endif // is_mpi
  
  fileStreams.push_back(&finalOut);  
  writeFrame(fileStreams, currentTime);

#ifdef IS_MPI
  finalOut.close();
#endif
  
}

void DumpWriter::writeFrame( vector<ofstream*>& outFile, double currentTime ){

  const int BUFFERSIZE = 2000;
  const int MINIBUFFERSIZE = 100;

  char tempBuffer[BUFFERSIZE];  
  char writeLine[BUFFERSIZE];

  int i;
  unsigned int k;

#ifdef IS_MPI
  
  /*********************************************************************
   * Documentation?  You want DOCUMENTATION?
   * 
   * Why all the potatoes below?  
   *
   * To make a long story short, the original version of DumpWriter
   * worked in the most inefficient way possible.  Node 0 would 
   * poke each of the node for an individual atom's formatted data 
   * as node 0 worked its way down the global index. This was particularly 
   * inefficient since the method blocked all processors at every atom 
   * (and did it twice!).
   *
   * An intermediate version of DumpWriter could be described from Node
   * zero's perspective as follows:
   * 
   *  1) Have 100 of your friends stand in a circle.
   *  2) When you say go, have all of them start tossing potatoes at
   *     you (one at a time).
   *  3) Catch the potatoes.
   *
   * It was an improvement, but MPI has buffers and caches that could 
   * best be described in this analogy as "potato nets", so there's no 
   * need to block the processors atom-by-atom.
   * 
   * This new and improved DumpWriter works in an even more efficient 
   * way:
   * 
   *  1) Have 100 of your friend stand in a circle.
   *  2) When you say go, have them start tossing 5-pound bags of 
   *     potatoes at you.
   *  3) Once you've caught a friend's bag of potatoes,
   *     toss them a spud to let them know they can toss another bag.
   *
   * How's THAT for documentation?
   *
   *********************************************************************/

  int *potatoes;
  int myPotato;

  int nProc;
  int j, which_node, done, which_atom, local_index, currentIndex;
  double atomData[13];
  int isDirectional;
  char* atomTypeString;
  char MPIatomTypeString[MINIBUFFERSIZE];
  int nObjects;
  int msgLen; // the length of message actually recieved at master nodes
#endif //is_mpi

  double q[4], ji[3];
  DirectionalAtom* dAtom;
  double pos[3], vel[3];
  int nTotObjects;
  StuntDouble* sd;
  char* molName;
  vector<StuntDouble*> integrableObjects;
  vector<StuntDouble*>::iterator iter;
  nTotObjects = entry_plug->getTotIntegrableObjects();
#ifndef IS_MPI
  
  for(k = 0; k < outFile.size(); k++){
    *outFile[k] << nTotObjects << "\n";

    *outFile[k] << currentTime << ";\t"
               << entry_plug->Hmat[0][0] << "\t"
                     << entry_plug->Hmat[1][0] << "\t"
                     << entry_plug->Hmat[2][0] << ";\t"
               
               << entry_plug->Hmat[0][1] << "\t"
                     << entry_plug->Hmat[1][1] << "\t"
                     << entry_plug->Hmat[2][1] << ";\t"

                     << entry_plug->Hmat[0][2] << "\t"
                     << entry_plug->Hmat[1][2] << "\t"
                     << entry_plug->Hmat[2][2] << ";";

    //write out additional parameters, such as chi and eta
    *outFile[k] << entry_plug->the_integrator->getAdditionalParameters() << endl;
  }
  
  for( i=0; i< entry_plug->n_mol; i++ ){

    integrableObjects = entry_plug->molecules[i].getIntegrableObjects();
    molName = (entry_plug->compStamps[entry_plug->molecules[i].getStampID()])->getID();
    
    for( iter = integrableObjects.begin();iter !=  integrableObjects.end(); ++iter){
      sd = *iter;
      sd->getPos(pos);
      sd->getVel(vel);

      sprintf( tempBuffer,
             "%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t",
             sd->getType(),
             pos[0],
             pos[1],
             pos[2],
             vel[0],
             vel[1],
             vel[2]);
      strcpy( writeLine, tempBuffer );

      if( sd->isDirectional() ){

        sd->getQ( q );
        sd->getJ( ji );

        sprintf( tempBuffer,
               "%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\n",
               q[0],
               q[1],
               q[2],
               q[3],
                 ji[0],
                 ji[1],
                 ji[2]);
        strcat( writeLine, tempBuffer );
      }
      else
        strcat( writeLine, "0.0\t0.0\t0.0\t0.0\t0.0\t0.0\t0.0\n" );
    
      for(k = 0; k < outFile.size(); k++)
        *outFile[k] << writeLine;      
    }
    
  }

#else // is_mpi

  /* code to find maximum tag value */
  
  int *tagub, flag, MAXTAG;
  MPI_Attr_get(MPI_COMM_WORLD, MPI_TAG_UB, &tagub, &flag);
  if (flag) {
    MAXTAG = *tagub;
  } else {
    MAXTAG = 32767;
  }  

  int haveError;

  MPI_Status istatus;
  int nCurObj;
  int *MolToProcMap = mpiSim->getMolToProcMap();

  // write out header and node 0's coordinates

  if( worldRank == 0 ){

    // Node 0 needs a list of the magic potatoes for each processor;

    nProc = mpiSim->getNProcessors();
    potatoes = new int[nProc];

    //write out the comment lines
    for (i = 0; i < nProc; i++) 
      potatoes[i] = 0;
    
    for(k = 0; k < outFile.size(); k++){
      *outFile[k] << nTotObjects << "\n";
      
      *outFile[k] << currentTime << ";\t"
                  << entry_plug->Hmat[0][0] << "\t"
                  << entry_plug->Hmat[1][0] << "\t"
                  << entry_plug->Hmat[2][0] << ";\t"
        
                  << entry_plug->Hmat[0][1] << "\t"
                  << entry_plug->Hmat[1][1] << "\t"
                  << entry_plug->Hmat[2][1] << ";\t"
        
                  << entry_plug->Hmat[0][2] << "\t"
                  << entry_plug->Hmat[1][2] << "\t"
                  << entry_plug->Hmat[2][2] << ";";
      
      *outFile[k] << entry_plug->the_integrator->getAdditionalParameters() 
                  << endl;
    }
    
    currentIndex = 0;
    
    for (i = 0 ; i < mpiSim->getNMolGlobal(); i++ ) {
      
      // Get the Node number which has this atom;
      
      which_node = MolToProcMap[i];
      
      if (which_node != 0) {
        
        if (potatoes[which_node] + 1 >= MAXTAG) {
          // The potato was going to exceed the maximum value, 
          // so wrap this processor potato back to 0:         

          potatoes[which_node] = 0;          
          MPI_Send(&potatoes[which_node], 1, MPI_INT, which_node, 0, 
                   MPI_COMM_WORLD);
          
        }

        myPotato = potatoes[which_node];        

        //recieve the number of integrableObject in current molecule
        MPI_Recv(&nCurObj, 1, MPI_INT, which_node,
                 myPotato, MPI_COMM_WORLD, &istatus);
        myPotato++;
        
        for(int l = 0; l < nCurObj; l++){

          if (potatoes[which_node] + 2 >= MAXTAG) {
            // The potato was going to exceed the maximum value, 
            // so wrap this processor potato back to 0:         

            potatoes[which_node] = 0;          
            MPI_Send(&potatoes[which_node], 1, MPI_INT, which_node, 0, MPI_COMM_WORLD);
            
          }

          MPI_Recv(MPIatomTypeString, MINIBUFFERSIZE, MPI_CHAR, which_node,
          myPotato, MPI_COMM_WORLD, &istatus);

          atomTypeString = MPIatomTypeString;

          myPotato++;

          MPI_Recv(atomData, 13, MPI_DOUBLE, which_node, myPotato, MPI_COMM_WORLD, &istatus);
          myPotato++;

          MPI_Get_count(&istatus, MPI_DOUBLE, &msgLen);

          if(msgLen  == 13) 
            isDirectional = 1;
          else
            isDirectional = 0;
          
          // If we've survived to here, format the line:
            
          if (!isDirectional) {
        
            sprintf( writeLine,
                 "%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t",
                 atomTypeString,
                 atomData[0],
                 atomData[1],
                 atomData[2],
                 atomData[3],
                 atomData[4],
                 atomData[5]);
        
           strcat( writeLine, "0.0\t0.0\t0.0\t0.0\t0.0\t0.0\t0.0\n" );
        
          } 
          else {
        
                sprintf( writeLine,
                         "%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\n",
                         atomTypeString,
                         atomData[0],
                         atomData[1],
                         atomData[2],
                         atomData[3],
                         atomData[4],
                         atomData[5],
                         atomData[6],
                         atomData[7],
                         atomData[8],
                         atomData[9],
                         atomData[10],
                         atomData[11],
                         atomData[12]);
            
          }
          
          for(k = 0; k < outFile.size(); k++)
            *outFile[k] << writeLine;            

        }// end for(int l =0)
        potatoes[which_node] = myPotato;
        
      }
      else {
        
        haveError = 0;
        
            local_index = indexArray[currentIndex].first;        
            
            integrableObjects = (entry_plug->molecules[local_index]).getIntegrableObjects(); 

        for(iter= integrableObjects.begin(); iter != integrableObjects.end(); ++iter){    
                sd = *iter;
            atomTypeString = sd->getType();
            
            sd->getPos(pos);
            sd->getVel(vel);          
          
            atomData[0] = pos[0];
            atomData[1] = pos[1];
            atomData[2] = pos[2];

            atomData[3] = vel[0];
            atomData[4] = vel[1];
            atomData[5] = vel[2];
              
            isDirectional = 0;

            if( sd->isDirectional() ){

              isDirectional = 1;
                
              sd->getQ( q );
              sd->getJ( ji );

              for (int j = 0; j < 6 ; j++)
                atomData[j] = atomData[j];            
              
              atomData[6] = q[0];
              atomData[7] = q[1];
              atomData[8] = q[2];
              atomData[9] = q[3];
              
              atomData[10] = ji[0];
              atomData[11] = ji[1];
              atomData[12] = ji[2];
            }
            
            // If we've survived to here, format the line:
            
            if (!isDirectional) {
        
              sprintf( writeLine,
                 "%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t",
                 atomTypeString,
                 atomData[0],
                 atomData[1],
                 atomData[2],
                 atomData[3],
                 atomData[4],
                 atomData[5]);
        
             strcat( writeLine, "0.0\t0.0\t0.0\t0.0\t0.0\t0.0\t0.0\n" );
        
            } 
            else {
        
                sprintf( writeLine,
                         "%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\n",
                         atomTypeString,
                         atomData[0],
                         atomData[1],
                         atomData[2],
                         atomData[3],
                         atomData[4],
                         atomData[5],
                         atomData[6],
                         atomData[7],
                         atomData[8],
                         atomData[9],
                         atomData[10],
                         atomData[11],
                         atomData[12]);
              
            }
            
            for(k = 0; k < outFile.size(); k++)
              *outFile[k] << writeLine;
            
            
        }//end for(iter = integrableObject.begin())
        
      currentIndex++;
      }

    }//end for(i = 0; i < mpiSim->getNmol())
    
    for(k = 0; k < outFile.size(); k++)
      outFile[k]->flush();
    
    sprintf( checkPointMsg,
             "Sucessfully took a dump.\n");
    
    MPIcheckPoint();        
    
    delete[] potatoes;
    
  } else {

    // worldRank != 0, so I'm a remote node.  

    // Set my magic potato to 0:

    myPotato = 0;
    currentIndex = 0;
    
    for (i = 0 ; i < mpiSim->getNMolGlobal(); i++ ) {
      
      // Am I the node which has this integrableObject?
      
      if (MolToProcMap[i] == worldRank) {


        if (myPotato + 1 >= MAXTAG) {
          
          // The potato was going to exceed the maximum value, 
          // so wrap this processor potato back to 0 (and block until
          // node 0 says we can go:
          
          MPI_Recv(&myPotato, 1, MPI_INT, 0, 0, MPI_COMM_WORLD, &istatus);
          
        }

          local_index = indexArray[currentIndex].first;        
          integrableObjects = entry_plug->molecules[local_index].getIntegrableObjects();
          
          nCurObj = integrableObjects.size();
                      
          MPI_Send(&nCurObj, 1, MPI_INT, 0,
                   myPotato, MPI_COMM_WORLD);
          myPotato++;

          for( iter = integrableObjects.begin(); iter  != integrableObjects.end(); iter++){

            if (myPotato + 2 >= MAXTAG) {
          
              // The potato was going to exceed the maximum value, 
              // so wrap this processor potato back to 0 (and block until
              // node 0 says we can go:
          
              MPI_Recv(&myPotato, 1, MPI_INT, 0, 0, MPI_COMM_WORLD, &istatus);
              
            }
            
            sd = *iter;
            
            atomTypeString = sd->getType();

            sd->getPos(pos);
            sd->getVel(vel);

            atomData[0] = pos[0];
            atomData[1] = pos[1];
            atomData[2] = pos[2];

            atomData[3] = vel[0];
            atomData[4] = vel[1];
            atomData[5] = vel[2];
              
            isDirectional = 0;

            if( sd->isDirectional() ){

                isDirectional = 1;
                
                sd->getQ( q );
                sd->getJ( ji );
                
                
                atomData[6] = q[0];
                atomData[7] = q[1];
                atomData[8] = q[2];
                atomData[9] = q[3];
      
                atomData[10] = ji[0];
                atomData[11] = ji[1];
                atomData[12] = ji[2];
              }

             
            strncpy(MPIatomTypeString, atomTypeString, MINIBUFFERSIZE);

            // null terminate the string before sending (just in case):
            MPIatomTypeString[MINIBUFFERSIZE-1] = '\0';

            MPI_Send(MPIatomTypeString, MINIBUFFERSIZE, MPI_CHAR, 0,
                             myPotato, MPI_COMM_WORLD);
            
            myPotato++;
            
            if (isDirectional) {

              MPI_Send(atomData, 13, MPI_DOUBLE, 0,
                       myPotato, MPI_COMM_WORLD);
              
            } else {

              MPI_Send(atomData, 6, MPI_DOUBLE, 0,
                       myPotato, MPI_COMM_WORLD);
            }

            myPotato++;  

          }

          currentIndex++;    
          
        }
      
      }

    sprintf( checkPointMsg,
             "Successfully took a dump.\n");
    MPIcheckPoint();                
    
  }
  
#endif // is_mpi
}

#ifdef IS_MPI

// a couple of functions to let us escape the write loop

void dWrite::DieDieDie( void ){

  MPI_Finalize();
  exit (0);
}

#endif //is_mpi
Revision:	221
Committed:	Tue Nov 23 22:48:31 2004 UTC (20 years, 11 months ago) by chrisfen
File size:	17366 byte(s)
Log Message:	Improvements to restraints
#	Content
1	#define _LARGEFILE_SOURCE64
2	#define _FILE_OFFSET_BITS 64
3
4	#include <string.h>
5	#include <iostream>
6	#include <fstream>
7	#include <algorithm>
8	#include <utility>
9
10	#ifdef IS_MPI
11	#include <mpi.h>
12	#include "brains/mpiSimulation.hpp"
13
14	namespace dWrite{
15	void DieDieDie( void );
16	}
17
18	using namespace dWrite;
19	#endif //is_mpi
20
21	#include "io/ReadWrite.hpp"
22	#include "utils/simError.h"
23
24	DumpWriter::DumpWriter( SimInfo* the_entry_plug ){
25
26	entry_plug = the_entry_plug;
27
28	#ifdef IS_MPI
29	if(worldRank == 0 ){
30	#endif // is_mpi
31
32	dumpFile.open(entry_plug->sampleName.c_str(), ios::out \| ios::trunc );
33
34	if( !dumpFile ){
35
36	sprintf( painCave.errMsg,
37	"Could not open \"%s\" for dump output.\n",
38	entry_plug->sampleName.c_str());
39	painCave.isFatal = 1;
40	simError();
41	}
42
43	#ifdef IS_MPI
44	}
45
46	//sort the local atoms by global index
47	sortByGlobalIndex();
48
49	sprintf( checkPointMsg,
50	"Sucessfully opened output file for dumping.\n");
51	MPIcheckPoint();
52	#endif // is_mpi
53	}
54
55	DumpWriter::~DumpWriter( ){
56
57	#ifdef IS_MPI
58	if(worldRank == 0 ){
59	#endif // is_mpi
60
61	dumpFile.close();
62
63	#ifdef IS_MPI
64	}
65	#endif // is_mpi
66	}
67
68	#ifdef IS_MPI
69
70	/**
71	* A hook function to load balancing
72	*/
73
74	void DumpWriter::update(){
75	sortByGlobalIndex();
76	}
77
78	/**
79	* Auxiliary sorting function
80	*/
81
82	bool indexSortingCriterion(const pair<int, int>& p1, const pair<int, int>& p2){
83	return p1.second < p2.second;
84	}
85
86	/**
87	* Sorting the local index by global index
88	*/
89
90	void DumpWriter::sortByGlobalIndex(){
91	Molecule* mols = entry_plug->molecules;
92	indexArray.clear();
93
94	for(int i = 0; i < entry_plug->n_mol;i++)
95	indexArray.push_back(make_pair(i, mols[i].getGlobalIndex()));
96
97	sort(indexArray.begin(), indexArray.end(), indexSortingCriterion);
98	}
99
100	#endif
101
102	void DumpWriter::writeDump(double currentTime){
103
104	ofstream finalOut;
105	vector<ofstream*> fileStreams;
106
107	#ifdef IS_MPI
108	if(worldRank == 0 ){
109	#endif
110	finalOut.open( entry_plug->finalName.c_str(), ios::out \| ios::trunc );
111	if( !finalOut ){
112	sprintf( painCave.errMsg,
113	"Could not open \"%s\" for final dump output.\n",
114	entry_plug->finalName.c_str() );
115	painCave.isFatal = 1;
116	simError();
117	}
118	#ifdef IS_MPI
119	}
120	#endif // is_mpi
121
122	fileStreams.push_back(&finalOut);
123	fileStreams.push_back(&dumpFile);
124
125	writeFrame(fileStreams, currentTime);
126
127	#ifdef IS_MPI
128	finalOut.close();
129	#endif
130
131	}
132
133	void DumpWriter::writeFinal(double currentTime){
134
135	ofstream finalOut;
136	vector<ofstream*> fileStreams;
137
138	#ifdef IS_MPI
139	if(worldRank == 0 ){
140	#endif // is_mpi
141
142	finalOut.open( entry_plug->finalName.c_str(), ios::out \| ios::trunc );
143
144	if( !finalOut ){
145	sprintf( painCave.errMsg,
146	"Could not open \"%s\" for final dump output.\n",
147	entry_plug->finalName.c_str() );
148	painCave.isFatal = 1;
149	simError();
150	}
151
152	#ifdef IS_MPI
153	}
154	#endif // is_mpi
155
156	fileStreams.push_back(&finalOut);
157	writeFrame(fileStreams, currentTime);
158
159	#ifdef IS_MPI
160	finalOut.close();
161	#endif
162
163	}
164
165	void DumpWriter::writeFrame( vector<ofstream*>& outFile, double currentTime ){
166
167	const int BUFFERSIZE = 2000;
168	const int MINIBUFFERSIZE = 100;
169
170	char tempBuffer[BUFFERSIZE];
171	char writeLine[BUFFERSIZE];
172
173	int i;
174	unsigned int k;
175
176	#ifdef IS_MPI
177
178	/*********************************************************************
179	* Documentation? You want DOCUMENTATION?
180	*
181	* Why all the potatoes below?
182	*
183	* To make a long story short, the original version of DumpWriter
184	* worked in the most inefficient way possible. Node 0 would
185	* poke each of the node for an individual atom's formatted data
186	* as node 0 worked its way down the global index. This was particularly
187	* inefficient since the method blocked all processors at every atom
188	* (and did it twice!).
189	*
190	* An intermediate version of DumpWriter could be described from Node
191	* zero's perspective as follows:
192	*
193	* 1) Have 100 of your friends stand in a circle.
194	* 2) When you say go, have all of them start tossing potatoes at
195	* you (one at a time).
196	* 3) Catch the potatoes.
197	*
198	* It was an improvement, but MPI has buffers and caches that could
199	* best be described in this analogy as "potato nets", so there's no
200	* need to block the processors atom-by-atom.
201	*
202	* This new and improved DumpWriter works in an even more efficient
203	* way:
204	*
205	* 1) Have 100 of your friend stand in a circle.
206	* 2) When you say go, have them start tossing 5-pound bags of
207	* potatoes at you.
208	* 3) Once you've caught a friend's bag of potatoes,
209	* toss them a spud to let them know they can toss another bag.
210	*
211	* How's THAT for documentation?
212	*
213	*********************************************************************/
214
215	int *potatoes;
216	int myPotato;
217
218	int nProc;
219	int j, which_node, done, which_atom, local_index, currentIndex;
220	double atomData[13];
221	int isDirectional;
222	char* atomTypeString;
223	char MPIatomTypeString[MINIBUFFERSIZE];
224	int nObjects;
225	int msgLen; // the length of message actually recieved at master nodes
226	#endif //is_mpi
227
228	double q[4], ji[3];
229	DirectionalAtom* dAtom;
230	double pos[3], vel[3];
231	int nTotObjects;
232	StuntDouble* sd;
233	char* molName;
234	vector<StuntDouble*> integrableObjects;
235	vector<StuntDouble*>::iterator iter;
236	nTotObjects = entry_plug->getTotIntegrableObjects();
237	#ifndef IS_MPI
238
239	for(k = 0; k < outFile.size(); k++){
240	*outFile[k] << nTotObjects << "\n";
241
242	*outFile[k] << currentTime << ";\t"
243	<< entry_plug->Hmat[0][0] << "\t"
244	<< entry_plug->Hmat[1][0] << "\t"
245	<< entry_plug->Hmat[2][0] << ";\t"
246
247	<< entry_plug->Hmat[0][1] << "\t"
248	<< entry_plug->Hmat[1][1] << "\t"
249	<< entry_plug->Hmat[2][1] << ";\t"
250
251	<< entry_plug->Hmat[0][2] << "\t"
252	<< entry_plug->Hmat[1][2] << "\t"
253	<< entry_plug->Hmat[2][2] << ";";
254
255	//write out additional parameters, such as chi and eta
256	*outFile[k] << entry_plug->the_integrator->getAdditionalParameters() << endl;
257	}
258
259	for( i=0; i< entry_plug->n_mol; i++ ){
260
261	integrableObjects = entry_plug->molecules[i].getIntegrableObjects();
262	molName = (entry_plug->compStamps[entry_plug->molecules[i].getStampID()])->getID();
263
264	for( iter = integrableObjects.begin();iter != integrableObjects.end(); ++iter){
265	sd = *iter;
266	sd->getPos(pos);
267	sd->getVel(vel);
268
269	sprintf( tempBuffer,
270	"%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t",
271	sd->getType(),
272	pos[0],
273	pos[1],
274	pos[2],
275	vel[0],
276	vel[1],
277	vel[2]);
278	strcpy( writeLine, tempBuffer );
279
280	if( sd->isDirectional() ){
281
282	sd->getQ( q );
283	sd->getJ( ji );
284
285	sprintf( tempBuffer,
286	"%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\n",
287	q[0],
288	q[1],
289	q[2],
290	q[3],
291	ji[0],
292	ji[1],
293	ji[2]);
294	strcat( writeLine, tempBuffer );
295	}
296	else
297	strcat( writeLine, "0.0\t0.0\t0.0\t0.0\t0.0\t0.0\t0.0\n" );
298
299	for(k = 0; k < outFile.size(); k++)
300	*outFile[k] << writeLine;
301	}
302
303	}
304
305	#else // is_mpi
306
307	/* code to find maximum tag value */
308
309	int *tagub, flag, MAXTAG;
310	MPI_Attr_get(MPI_COMM_WORLD, MPI_TAG_UB, &tagub, &flag);
311	if (flag) {
312	MAXTAG = *tagub;
313	} else {
314	MAXTAG = 32767;
315	}
316
317	int haveError;
318
319	MPI_Status istatus;
320	int nCurObj;
321	int *MolToProcMap = mpiSim->getMolToProcMap();
322
323	// write out header and node 0's coordinates
324
325	if( worldRank == 0 ){
326
327	// Node 0 needs a list of the magic potatoes for each processor;
328
329	nProc = mpiSim->getNProcessors();
330	potatoes = new int[nProc];
331
332	//write out the comment lines
333	for (i = 0; i < nProc; i++)
334	potatoes[i] = 0;
335
336	for(k = 0; k < outFile.size(); k++){
337	*outFile[k] << nTotObjects << "\n";
338
339	*outFile[k] << currentTime << ";\t"
340	<< entry_plug->Hmat[0][0] << "\t"
341	<< entry_plug->Hmat[1][0] << "\t"
342	<< entry_plug->Hmat[2][0] << ";\t"
343
344	<< entry_plug->Hmat[0][1] << "\t"
345	<< entry_plug->Hmat[1][1] << "\t"
346	<< entry_plug->Hmat[2][1] << ";\t"
347
348	<< entry_plug->Hmat[0][2] << "\t"
349	<< entry_plug->Hmat[1][2] << "\t"
350	<< entry_plug->Hmat[2][2] << ";";
351
352	*outFile[k] << entry_plug->the_integrator->getAdditionalParameters()
353	<< endl;
354	}
355
356	currentIndex = 0;
357
358	for (i = 0 ; i < mpiSim->getNMolGlobal(); i++ ) {
359
360	// Get the Node number which has this atom;
361
362	which_node = MolToProcMap[i];
363
364	if (which_node != 0) {
365
366	if (potatoes[which_node] + 1 >= MAXTAG) {
367	// The potato was going to exceed the maximum value,
368	// so wrap this processor potato back to 0:
369
370	potatoes[which_node] = 0;
371	MPI_Send(&potatoes[which_node], 1, MPI_INT, which_node, 0,
372	MPI_COMM_WORLD);
373
374	}
375
376	myPotato = potatoes[which_node];
377
378	//recieve the number of integrableObject in current molecule
379	MPI_Recv(&nCurObj, 1, MPI_INT, which_node,
380	myPotato, MPI_COMM_WORLD, &istatus);
381	myPotato++;
382
383	for(int l = 0; l < nCurObj; l++){
384
385	if (potatoes[which_node] + 2 >= MAXTAG) {
386	// The potato was going to exceed the maximum value,
387	// so wrap this processor potato back to 0:
388
389	potatoes[which_node] = 0;
390	MPI_Send(&potatoes[which_node], 1, MPI_INT, which_node, 0, MPI_COMM_WORLD);
391
392	}
393
394	MPI_Recv(MPIatomTypeString, MINIBUFFERSIZE, MPI_CHAR, which_node,
395	myPotato, MPI_COMM_WORLD, &istatus);
396
397	atomTypeString = MPIatomTypeString;
398
399	myPotato++;
400
401	MPI_Recv(atomData, 13, MPI_DOUBLE, which_node, myPotato, MPI_COMM_WORLD, &istatus);
402	myPotato++;
403
404	MPI_Get_count(&istatus, MPI_DOUBLE, &msgLen);
405
406	if(msgLen == 13)
407	isDirectional = 1;
408	else
409	isDirectional = 0;
410
411	// If we've survived to here, format the line:
412
413	if (!isDirectional) {
414
415	sprintf( writeLine,
416	"%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t",
417	atomTypeString,
418	atomData[0],
419	atomData[1],
420	atomData[2],
421	atomData[3],
422	atomData[4],
423	atomData[5]);
424
425	strcat( writeLine, "0.0\t0.0\t0.0\t0.0\t0.0\t0.0\t0.0\n" );
426
427	}
428	else {
429
430	sprintf( writeLine,
431	"%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\n",
432	atomTypeString,
433	atomData[0],
434	atomData[1],
435	atomData[2],
436	atomData[3],
437	atomData[4],
438	atomData[5],
439	atomData[6],
440	atomData[7],
441	atomData[8],
442	atomData[9],
443	atomData[10],
444	atomData[11],
445	atomData[12]);
446
447	}
448
449	for(k = 0; k < outFile.size(); k++)
450	*outFile[k] << writeLine;
451
452	}// end for(int l =0)
453	potatoes[which_node] = myPotato;
454
455	}
456	else {
457
458	haveError = 0;
459
460	local_index = indexArray[currentIndex].first;
461
462	integrableObjects = (entry_plug->molecules[local_index]).getIntegrableObjects();
463
464	for(iter= integrableObjects.begin(); iter != integrableObjects.end(); ++iter){
465	sd = *iter;
466	atomTypeString = sd->getType();
467
468	sd->getPos(pos);
469	sd->getVel(vel);
470
471	atomData[0] = pos[0];
472	atomData[1] = pos[1];
473	atomData[2] = pos[2];
474
475	atomData[3] = vel[0];
476	atomData[4] = vel[1];
477	atomData[5] = vel[2];
478
479	isDirectional = 0;
480
481	if( sd->isDirectional() ){
482
483	isDirectional = 1;
484
485	sd->getQ( q );
486	sd->getJ( ji );
487
488	for (int j = 0; j < 6 ; j++)
489	atomData[j] = atomData[j];
490
491	atomData[6] = q[0];
492	atomData[7] = q[1];
493	atomData[8] = q[2];
494	atomData[9] = q[3];
495
496	atomData[10] = ji[0];
497	atomData[11] = ji[1];
498	atomData[12] = ji[2];
499	}
500
501	// If we've survived to here, format the line:
502
503	if (!isDirectional) {
504
505	sprintf( writeLine,
506	"%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t",
507	atomTypeString,
508	atomData[0],
509	atomData[1],
510	atomData[2],
511	atomData[3],
512	atomData[4],
513	atomData[5]);
514
515	strcat( writeLine, "0.0\t0.0\t0.0\t0.0\t0.0\t0.0\t0.0\n" );
516
517	}
518	else {
519
520	sprintf( writeLine,
521	"%s\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\t%lf\n",
522	atomTypeString,
523	atomData[0],
524	atomData[1],
525	atomData[2],
526	atomData[3],
527	atomData[4],
528	atomData[5],
529	atomData[6],
530	atomData[7],
531	atomData[8],
532	atomData[9],
533	atomData[10],
534	atomData[11],
535	atomData[12]);
536
537	}
538
539	for(k = 0; k < outFile.size(); k++)
540	*outFile[k] << writeLine;
541
542
543	}//end for(iter = integrableObject.begin())
544
545	currentIndex++;
546	}
547
548	}//end for(i = 0; i < mpiSim->getNmol())
549
550	for(k = 0; k < outFile.size(); k++)
551	outFile[k]->flush();
552
553	sprintf( checkPointMsg,
554	"Sucessfully took a dump.\n");
555
556	MPIcheckPoint();
557
558	delete[] potatoes;
559
560	} else {
561
562	// worldRank != 0, so I'm a remote node.
563
564	// Set my magic potato to 0:
565
566	myPotato = 0;
567	currentIndex = 0;
568
569	for (i = 0 ; i < mpiSim->getNMolGlobal(); i++ ) {
570
571	// Am I the node which has this integrableObject?
572
573	if (MolToProcMap[i] == worldRank) {
574
575
576	if (myPotato + 1 >= MAXTAG) {
577
578	// The potato was going to exceed the maximum value,
579	// so wrap this processor potato back to 0 (and block until
580	// node 0 says we can go:
581
582	MPI_Recv(&myPotato, 1, MPI_INT, 0, 0, MPI_COMM_WORLD, &istatus);
583
584	}
585
586	local_index = indexArray[currentIndex].first;
587	integrableObjects = entry_plug->molecules[local_index].getIntegrableObjects();
588
589	nCurObj = integrableObjects.size();
590
591	MPI_Send(&nCurObj, 1, MPI_INT, 0,
592	myPotato, MPI_COMM_WORLD);
593	myPotato++;
594
595	for( iter = integrableObjects.begin(); iter != integrableObjects.end(); iter++){
596
597	if (myPotato + 2 >= MAXTAG) {
598
599	// The potato was going to exceed the maximum value,
600	// so wrap this processor potato back to 0 (and block until
601	// node 0 says we can go:
602
603	MPI_Recv(&myPotato, 1, MPI_INT, 0, 0, MPI_COMM_WORLD, &istatus);
604
605	}
606
607	sd = *iter;
608
609	atomTypeString = sd->getType();
610
611	sd->getPos(pos);
612	sd->getVel(vel);
613
614	atomData[0] = pos[0];
615	atomData[1] = pos[1];
616	atomData[2] = pos[2];
617
618	atomData[3] = vel[0];
619	atomData[4] = vel[1];
620	atomData[5] = vel[2];
621
622	isDirectional = 0;
623
624	if( sd->isDirectional() ){
625
626	isDirectional = 1;
627
628	sd->getQ( q );
629	sd->getJ( ji );
630
631
632	atomData[6] = q[0];
633	atomData[7] = q[1];
634	atomData[8] = q[2];
635	atomData[9] = q[3];
636
637	atomData[10] = ji[0];
638	atomData[11] = ji[1];
639	atomData[12] = ji[2];
640	}
641
642
643	strncpy(MPIatomTypeString, atomTypeString, MINIBUFFERSIZE);
644
645	// null terminate the string before sending (just in case):
646	MPIatomTypeString[MINIBUFFERSIZE-1] = '\0';
647
648	MPI_Send(MPIatomTypeString, MINIBUFFERSIZE, MPI_CHAR, 0,
649	myPotato, MPI_COMM_WORLD);
650
651	myPotato++;
652
653	if (isDirectional) {
654
655	MPI_Send(atomData, 13, MPI_DOUBLE, 0,
656	myPotato, MPI_COMM_WORLD);
657
658	} else {
659
660	MPI_Send(atomData, 6, MPI_DOUBLE, 0,
661	myPotato, MPI_COMM_WORLD);
662	}
663
664	myPotato++;
665
666	}
667
668	currentIndex++;
669
670	}
671
672	}
673
674	sprintf( checkPointMsg,
675	"Successfully took a dump.\n");
676	MPIcheckPoint();
677
678	}
679
680	#endif // is_mpi
681	}
682
683	#ifdef IS_MPI
684
685	// a couple of functions to let us escape the write loop
686
687	void dWrite::DieDieDie( void ){
688
689	MPI_Finalize();
690	exit (0);
691	}
692
693	#endif //is_mpi