void
ParaCommMpiWorld::probe(
   int* source,
   int* tag
   )
{
   MPI::Status mpiStatus;
   MPI::COMM_WORLD.Probe(MPI::ANY_SOURCE, MPI::ANY_TAG, mpiStatus);
   *source = mpiStatus.Get_source();
   *tag = mpiStatus.Get_tag();
   TAG_TRACE (Probe, From, *source, *tag);
}
bool
ParaCommMpiWorld::iProbe(
   int* source,
   int* tag
   )
{
   bool flag;
   MPI::Status mpiStatus;
   flag = MPI::COMM_WORLD.Iprobe(MPI::ANY_SOURCE, MPI::ANY_TAG, mpiStatus);
   if( flag )
   {
      *source = mpiStatus.Get_source();
      *tag = mpiStatus.Get_tag();
      TAG_TRACE (Iprobe, From, *source, *tag);
   }
   return flag;
}
int
ParaCommMpiWorld::waitSpecTagFromSpecSource(
      const int source,
      const int datatypeId,
      const int tag,
      int *receivedTag
      )
{
   MPI::Status mpiStatus;
   MPI::COMM_WORLD.Probe(source, MPI::ANY_TAG, mpiStatus);
   (*receivedTag) = mpiStatus.Get_tag();
   TAG_TRACE (Probe, From, source, (*receivedTag));
   if( tag == (*receivedTag) )
   {
      return 0;
   }
   else
   {
      return 1;
   }
}
bool
ParaCommMpiWorld::waitToken(
      int tempRank
      )
{
   pthread_mutex_lock(&tokenAccessLock);
   if( token[0] == myRank )
   {
      pthread_mutex_unlock(&tokenAccessLock);
      return true;
   }
   else
   {
      int previousRank = myRank - 1;
      if( previousRank == 0 )
      {
         if( token[0] != -1 )
         {
            previousRank = comSize - 1;
         }
      }
      int receivedTag;
      MPI::Status mpiStatus;
      MPI::COMM_WORLD.Probe(MPI::ANY_SOURCE, MPI::ANY_TAG, mpiStatus);
      receivedTag = mpiStatus.Get_tag();
      TAG_TRACE (Probe, From, mpiStatus.Get_source(), receivedTag);
      if( receivedTag == TagToken )
      {
         receive(token, 2, ParaINT, 0, TagToken);
         assert(token[0] == myRank);
         pthread_mutex_unlock(&tokenAccessLock);
         return true;
      }
      else
      {
         pthread_mutex_unlock(&tokenAccessLock);
         return false;
      }
   }
}
Beispiel #5
0
void PSO::Swarm::evaluate_slave() {
  double f(log(0.0));
  int id(0);
  int flag(0);
  int tag(0);
  int dest(0);
  Point position(numParams);
  MPI::Status status;
//  fprintf(stderr,"Slave %d ready.\n",mpi_rank);
  while (1) {
//    flag = MPI::COMM_WORLD.Iprobe(0,MPI::ANY_TAG,status);
//    if (flag) {
//      tag = status.Get_tag();
    MPI::COMM_WORLD.Recv(&id,1,MPI::INT,0,MPI::ANY_TAG,status);
    if (status.Get_tag() == 0) break;
    MPI::COMM_WORLD.Recv(position.data(),numParams,MPI::DOUBLE,0,MPI::ANY_TAG,status);
    f = p->evalFunc(position,p->evalParams);
    MPI::COMM_WORLD.Send(&id,1,MPI::INT,0,2);
    MPI::COMM_WORLD.Send(&f,1,MPI::DOUBLE,0,2);
//    }
  }
//  fprintf(stderr,"Slave %d done.\n",mpi_rank);
}
Beispiel #6
0
int main(int argc, char** argv)
{
	//_CrtSetDbgFlag ( _CRTDBG_ALLOC_MEM_DF | _CRTDBG_LEAK_CHECK_DF );

	//_CrtMemState s1;
	//_CrtMemCheckpoint( &s1 );

	/* run multiple trials of Develep 
	   input: trial text file
	   first column: number of trials to run
	   second column: parameter file for trials
	   third column: data for trials
	*/
	
		string trialsetup(argv[1]);
       // cout << "trialsetup: " + trialsetup + "\n";
		int totaltrials = 0;
		vector<int> trialset; 
		vector<string> paramfile;
		vector<string> datafile;

		ifstream fs(trialsetup);
		getTrialSetup(fs,totaltrials,trialset,paramfile,datafile);
		
		int numsent=0;

		//MPI stuff
		int master=0;
		int ierr;
		MPI::Init();
		int numprocs = MPI::COMM_WORLD.Get_size();
		int myid = MPI::COMM_WORLD.Get_rank();
		//cout << "I am process " + to_string(static_cast<long long>(myid)) + " of " + to_string(static_cast<long long>(numprocs)) + "\n";
		MPI::Status status;
		//const char * pbuff,dbuff;
     try
	 {   
		if (myid==master){
        	//cout << "total trials: " + to_string(static_cast<long long>(totaltrials)) + "\n";
        	//cout << "In master loop\n";
        	cout << "Running trials of ellenGP: \n Number of trials: " + to_string(static_cast<long long>(totaltrials)) +"\n Number of processors: " + to_string(static_cast<long long>(numprocs)) + "\n";

        	// schedule tasks from master node
        	for (int i=0;i<min(numprocs-1,totaltrials);i++){
        		//cout << "sending " + paramfile.at(i) + " to process " + to_string(static_cast<long long>(i)) + "\n";
        		MPI::COMM_WORLD.Send(paramfile.at(i).c_str(),paramfile.at(i).length(),MPI::CHAR,i+1,i+1);
        		//cout << "sending " + datafile.at(i) + " to process " + to_string(static_cast<long long>(i)) + "\n";
				MPI::COMM_WORLD.Send(datafile.at(i).c_str(),datafile.at(i).length(),MPI::CHAR,i+1,i+1);
				numsent++;
				//cout << "numsent: " + to_string(static_cast<long long>(numsent)) + "\n";
        	}
        	//int curnumsent=numsent;
        	int stops =0;
        	while(numsent<=totaltrials && stops<numprocs-1){
        		int ans;
        		MPI::COMM_WORLD.Recv(&ans,1,MPI::INT,MPI::ANY_SOURCE,MPI::ANY_TAG,status);
        		const int sender = status.Get_source();
        		//int anstype = status.Get_tag();
        		if (numsent < totaltrials){
        			MPI::COMM_WORLD.Send(paramfile.at(numsent).c_str(),paramfile.at(numsent).length(),MPI::CHAR,sender,numsent+1);
					MPI::COMM_WORLD.Send(datafile.at(numsent).c_str(),datafile.at(numsent).length(),MPI::CHAR,sender,numsent+1);
					++numsent;
        		}
        		else{
        			//cout << "sending stop command to process " + to_string(static_cast<long long>(sender)) + "\n";
        			MPI::COMM_WORLD.Send(MPI::BOTTOM,0,MPI::CHAR,sender,0);
        			++stops;
        		}

        	} cout << "out of master while loop\n";
        }
        else{
        	//cout << "in slave task \n";
        	// receive tasks and send completion messages to master
        	//cout << "in slave task. myid is " + to_string(static_cast<long long>(myid)) + " and totaltrials is " + to_string(static_cast<long long>(totaltrials)) + "\n";
        	bool cont = true;
        	while (cont){
				if (myid <= totaltrials){
					//char * pbuff,dbuff;
					//cout << "probe master status\n";
					MPI::COMM_WORLD.Probe(master, MPI::ANY_TAG, status);
					int l1 = status.Get_count(MPI::CHAR);
					char * pbuff = new char[l1];
					//cout << "Receive packet\n";
					MPI::COMM_WORLD.Recv(pbuff,l1,MPI::CHAR,master, MPI::ANY_TAG,status);
					//cout << "received pbuff value: " + string(pbuff) + "\n";
					if(status.Get_tag() !=0 ){

						MPI::COMM_WORLD.Probe(master, MPI::ANY_TAG, status);
						int l2 = status.Get_count(MPI::CHAR);
						char * dbuff = new char[l2];
						MPI::COMM_WORLD.Recv(dbuff,l2,MPI::CHAR,master, MPI::ANY_TAG,status);
						//cout << "received dbuff value: " + string(dbuff) + "\n";
						if(status.Get_tag() !=0 ){
							int tag = status.Get_tag();
							string pfile(pbuff,l1);
							string dfile(dbuff,l2);
							cout << "running process " + to_string(static_cast<long long>(tag)) + " of " + to_string(static_cast<long long>(totaltrials)) + " on processor " + to_string(static_cast<long long>(myid)) + " : " + pfile.substr(pfile.rfind('/')+1,pfile.size()) + ", " + dfile.substr(dfile.rfind('/')+1,dfile.size())  + "\n";
							//run develep
							runEllenGP(pfile,dfile,1,myid);
							//cout << "hello\n";
							cout << "\nfinished process " + to_string(static_cast<long long>(tag)) + " of " + to_string(static_cast<long long>(totaltrials)) + " on processor " + to_string(static_cast<long long>(myid)) + " : " + pfile.substr(pfile.rfind('/')+1,pfile.size()) + ", " + dfile.substr(dfile.rfind('/')+1,dfile.size())  + "\n";

							// send message when finished
							int tmp = 1;
							MPI::COMM_WORLD.Send(&tmp,1,MPI::INT,master,myid);
						}
						else{
							//cout << "status tag is zero on process " + to_string(static_cast<long long>(myid)) + "\n";
							cont=false;

						}


						delete [] dbuff;
					}
					else{
						//cout << "status tag is zero on process " + to_string(static_cast<long long>(myid)) + "\n";
						cont=false;
					}

					delete [] pbuff;

				}
        	}


        }





		MPI::Finalize();
		char key;
		if(myid==master)
			cout << "All trials completed. Exiting..." << endl;
		//key = getchar();
	}
	catch(const std::bad_alloc&)
	{
		cout << "bad allocation error from processor " << to_string(static_cast<long long>(myid)) << "\n";
		exit(1);
	}
	catch(exception& er) 
	{
		cout << "Error: " << er.what() << endl;
		exit(1);

	}
	catch(...)
	{
		cout << "Exception Occurred."<<endl;
		exit(1);
	}
	return 0;
}
Beispiel #7
0
int main(int argc, char * argv[]){

	int tag, send_tag;
        int to,from;
	int st_count, st_source, st_tag;
	double start_time = 0.0;
	double end_time = 0.0;
	MPI::Status status;

	MPI::Init(argc, argv);
	int rank = MPI::COMM_WORLD.Get_rank();
	int size = MPI::COMM_WORLD.Get_size();
	MPI_Barrier(MPI_COMM_WORLD);
	start_time = MPI_Wtime();
	int option;

	opterr = 0;
	int N = 0;
	string web_file;

	while ((option = getopt(argc, argv, "l:n:"))!= -1)
	{
		switch (option)
		{
			case 'n':
				N = atoi(optarg);
			break;
			case 'l':
				web_file = string(optarg);
			break;
			case '?':
				if (optopt == 'n')
					cerr<< "Option -"<<char(optopt)<<" requires an argument." <<endl;
			        else if (isprint (optopt))
					cerr<< "Unknown option `-"<<char(optopt)<<"'.\n"<<endl;
				else
					cerr<<  "Unknown option character `"<<std::hex<<optopt<<"'."<<endl;
		}
	}

	vector<string> URLs;
	char buffer[1024];
	string line;
	system("rm -fr /tmp/xiw412/");
	system("mkdir /tmp/xiw412/");

	if(rank == 0)
	{	
		fstream fread_file(web_file.c_str(), ios::in);
		while (getline(fread_file, line)){
		URLs.push_back(line);
		}
	}

	if(rank == 0)
	{
		to = 0;
		send_tag = 0;
		int round = 0;

		while(round * size < URLs.size())
		{
			for(int i = round * size; i < (round + 1) * size && i < URLs.size(); i++)
			{
				sprintf(buffer, "%s", URLs[i].c_str());
				
				cout << rank << ":"<< "sending " << buffer << endl;
				MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, i%size, send_tag);
				to++;
				send_tag++;
			}

		
			tag = MPI::ANY_TAG;
			from = MPI::ANY_SOURCE;
			MPI::COMM_WORLD.Recv(buffer, 1024, MPI::CHAR, from, tag, status);
			st_count = status.Get_count(MPI::CHAR);
			st_source = status.Get_source();
			st_tag = status.Get_tag();
			
			string result("");
			result = parse(buffer, N);
			strcpy(buffer,result.c_str());

			MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, 0, st_tag);
			
			for(int i = round * size; i < (round + 1) * size && i < URLs.size(); i++)
			{
				tag = MPI::ANY_TAG;
				from = MPI::ANY_SOURCE;
				MPI::COMM_WORLD.Recv(buffer, 1024, MPI::CHAR, from, tag, status);
				st_count = status.Get_count(MPI::CHAR);
				st_source = status.Get_source();
				st_tag = status.Get_tag();

				cout << rank <<":" << "received from "<<st_source<<endl<< buffer << endl;
			}

			round++;
		}

		for (int i = 1; i < size; ++i)
		{
			strcpy(buffer, "Finish");
			MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, i, 0);
		}
	}
	else
	{
		while(1)
		{
			tag = MPI::ANY_TAG;
			from = MPI::ANY_SOURCE;
			MPI::COMM_WORLD.Recv(buffer, 1024, MPI::CHAR, from, tag, status);
			st_count = status.Get_count(MPI::CHAR);
			st_source = status.Get_source();
			st_tag = status.Get_tag();
//			cout<<" rank " << rank <<": " << "st_count:"<<st_count<<" st_source"<< st_source << " st_tag "<< st_tag << endl;
//			cout<<"         " << buffer <<endl;

			if (strcmp(buffer, "Finish") == 0)
				break;

			string result("");
			result = parse(buffer, N);
			strcpy(buffer,result.c_str());

			MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, 0, st_tag);
		}
	}

	cout << "rank " << rank <<": "<<"I am dying, goodbye!"<<endl;
	MPI_Barrier(MPI_COMM_WORLD);
	end_time = MPI_Wtime();
	printf("The running time is : %lf \n",end_time-start_time);
	MPI::Finalize();
	return 0;
}
Beispiel #8
0
void *mpi_thread(void *arg) {
    struct State *state = (struct State *)arg;

    int buf;
    MPI::Status status;
    set<int> queue;

    bool inside = false;

    while (1) {
        MPI::COMM_WORLD.Recv(&buf, 1, MPI::INT, MPI::ANY_SOURCE, MPI::ANY_TAG, status);
        state->lamport = max(state->lamport, buf) + 1;
        switch (status.Get_tag()) {
            case INSIDE_TAG: // enter/exit
                if (!inside) {
                    for (int i = 0; i < state->size; i++) {
                        if (i != state->rank) {
                            MPI::COMM_WORLD.Send(&state->lamport, 1, MPI::INT, i, REQUEST_TAG);
                        }
                    }
                    int request_clock = state->lamport;
                    int replies_received = 0;
                    while (replies_received < state->size - 1) {
                        MPI::COMM_WORLD.Recv(&buf, 1, MPI::INT, MPI::ANY_SOURCE, MPI::ANY_TAG, status);
                        state->lamport = max(state->lamport, buf) + 1;
                        switch (status.Get_tag()) {
                            case REQUEST_TAG:
                                if (request_clock < buf || (buf == request_clock && state->rank < status.Get_source())) {
                                    // current process has higher priority
                                    queue.insert(status.Get_source());
                                } else {
                                    // other process has higher priority
                                    MPI::COMM_WORLD.Send(&state->lamport, 1, MPI::INT, status.Get_source(), AGREE_TAG);
                                }
                                break;
                            case AGREE_TAG:
                                if (buf > request_clock) {
                                    replies_received++;
                                    log(state, "comm: Agree %d received from %d", buf, status.Get_source());
                                }
                                break;
                            default:
                                log(state, "comm: Unknown message tag %d", status.Get_tag());
                        }
                    }
                    inside = true;
                    unique_lock<mutex> lck(state->mtx);
                    state->ready = true;
                    state->cv.notify_all();
                    lck.unlock();
                } else {
                    // broadcast agree to all in queue
                    char *repr = (char *)malloc(1024);
                    *repr = '\0';
                    for (int p : queue) {
                        sprintf(repr + strlen(repr), "%d, ", p);
                    }
                    state->lamport++;
                    log(state, "comm: !!! LEFT, %s", repr);
                    free(repr);
                    for (int p : queue) {
                        MPI::COMM_WORLD.Send(&state->lamport, 1, MPI::INT, p, AGREE_TAG);
                    }
                    queue.clear();
                    inside = false;
                }
                break;
            case REQUEST_TAG:
                if (inside) {
                    queue.insert(status.Get_source());
                } else {
                    MPI::COMM_WORLD.Send(&state->lamport, 1, MPI::INT, status.Get_source(), AGREE_TAG);
                    state->lamport++;
                }
                break;
            case AGREE_TAG:
                break;
            default:
                log(state, "comm: Unknown message tag %d", status.Get_tag());
        }
    }
}
int main(int argc, char* argv[])
{
  int pid; //For rank of current process
  int no_of_process; //To find the total number of processes
  int size; //Size of processes to be allocated for each process.

  //Initializing the MPI environment
  MPI::Init ( argc, argv );

  //Getting the number of processes
  no_of_process = MPI::COMM_WORLD.Get_size();

  //Handling if run as a single application.
  if(no_of_process<2){
    cout<<"\n ERROR: You'll need atleast 2 processes to run this application.\n\n";
    MPI_Finalize();
    return 0;
  }

  //argv[1] - PERCENT OF KEYWORDS REQUIRED ; argv[2] - FOLDER PATH
  if(!argv[1] || !argv[2]){
    cout<<"\n\n Parameter not provided. Quitting\n";
    MPI_Finalize();
    return 0;
  }

  //Get the process ID
  pid = MPI::COMM_WORLD.Get_rank();

  // Process ID 0 => Initial Process
  if(pid==0){
  	  queue<string> que;
      que.push(string(argv[2],strlen(argv[2])));

      /********* INITIAL STRUCTURE TO HAVE SOME VALUES IN THE QUEUE ***************/

      string dir = que.front();
      que.pop();
      DIR *dp;
      struct dirent *dirp;

      if((dp = opendir(dir.c_str())) == NULL) {
        cout << "Error(" << errno << ") opening " << dir << endl;
        return errno;
      }

      while ((dirp = readdir(dp)) != NULL) {
        if(((string)dirp->d_name).compare(".")==0||((string)dirp->d_name).compare("..")==0){
          continue;
        }

        que.push(dir+"/"+string(dirp->d_name)); //If only this statement is present, we push all the files into the queue
      }
      closedir(dp);

      /********* INITIAL STRUCTURE TO HAVE SOME VALUES IN THE QUEUE ***************/


      while(!que.empty()){

        // ======== FUNCTION TO PRINT QUEUE VALUES ========

        queue<string> que3;
        que3=que;
        cout<<"\n\n PARENT Queue : "<<endl;
        //Temp function to print the value of the queue
        while(!que3.empty()){
          cout<<que3.front()<<endl;
          que3.pop();
        }

        //Allocate work to processes equally.
        int i=0;
        size=1; //By default, allocating one directory per process
        string buf; //Buffer to send the folders to the subordinate processes
        if(que.size()>(no_of_process-1)){
          size=ceil((float)que.size()/(no_of_process-1));
        }

        /************* PARENT SENDER PROCESS ***********************/
        /************* ===================== ***********************/
        while(!que.empty() && i<=no_of_process-1){
            int j=0;
            buf="";
            while(j<size && !que.empty()){
              buf+=que.front();
              que.pop();
              buf+=";";
              j++;
            }

         // MPI::Comm::Send(const void* buf, int count, MPI::Datatype& datatype, int dest, int tag)
            MPI::COMM_WORLD.Send(buf.c_str(), buf.length(), MPI::CHAR, i+1, i+1);
            i++;
        }

        /************* PARENT RECEIVER PROCESS ***********************/
        /************* ======================= ***********************/
        while(i>0){
          // cout<<"\n\n Process 0 Waiting to receive from child";
	        MPI::Status status;

          //Probe for values first
	        MPI::COMM_WORLD.Probe(MPI::ANY_SOURCE, MPI::ANY_TAG, status);

	        int l = status.Get_count(MPI::CHAR);
	        char *buf = new char[l];
	        const auto sender = status.Get_source();
	        const auto tag = status.Get_tag();

        //MPI::Comm::Recv(void* buf, int count, MPI::Datatype& datatype, int source, int tag, MPI::Status* status)
          MPI::COMM_WORLD.Recv(buf, l, MPI::CHAR, sender, tag, status);

	        string fname(buf, l);
	        delete [] buf;
	        vector<string> fnames;
	        boost::split(fnames, fname, boost::is_any_of(";"));

	        for(int k=0;k<fnames.size();k++){
            if(fnames[k].length())
            que.push(fnames[k]);
	        }
	        i--;
	       }
       }


       vector<int> processes_with_files; //Vector to store only the files with ranks
       set<string> queue_values;
       vector<string> vec_queue_values;

      /************* IF QUEUE EMPTY, PROCEED TO QUERY PROCESSING ***********************/
      /************* =========================================== ***********************/
      if(que.empty()){


        //Message asking children to send their file availability
        string send_rank_message="SEND IF YOU HAVE";

        //Send message to children to send if they have files with them
        for(int rank_values=1;rank_values<no_of_process;rank_values++){
          //MPI::Comm::Send(const void* buf, int count, MPI::Datatype& datatype, int dest, int tag)
          MPI::COMM_WORLD.Send(send_rank_message.c_str(), send_rank_message.length(), MPI::CHAR, rank_values, rank_values);
        }

        //Values for reception
        int rank_received[no_of_process];
        rank_received[0]=0; //Parent process - So excluding it.

        for(int rank_values=1;rank_values<no_of_process;rank_values++){
          //For probe status store
          MPI::Status status;
          //Probe for incoming values
          MPI::COMM_WORLD.Probe(MPI::ANY_SOURCE, MPI::ANY_TAG, status);
          //Get source and tag
          const auto sender = status.Get_source();
          const auto tag = status.Get_tag();
          //MPI::Comm::Recv(void* buf, int count, MPI::Datatype& datatype, int source, int tag, MPI::Status* status)
          MPI::COMM_WORLD.Recv(&rank_received[sender], 1, MPI::INT, sender, tag, status);
        }

        //String for rank values to be sent to all the child processes
        string processes_with_files_str="";

        //Storing the rank of processes that have files
        for(int i=1;i<no_of_process;i++){
          if(rank_received[i]==1){
            processes_with_files_str+= to_string(i) + ";";
            processes_with_files.push_back(i);
          }
        }

        string process_list_message = "ABOUT TO SEND PROCESS VALUES";
        for(int i=0;i<processes_with_files.size();i++){
          //MPI::Comm::Send(const void* buf, int count, MPI::Datatype& datatype, int dest, int tag)
          MPI::COMM_WORLD.Send(process_list_message.c_str(), process_list_message.length(), MPI::CHAR, processes_with_files[i], processes_with_files[i]);
          MPI::COMM_WORLD.Send(processes_with_files_str.c_str(), processes_with_files_str.length(), MPI::CHAR, processes_with_files[i], processes_with_files[i]);
          // cout<<"\n\n Parent has sent the value!\n";
        }


      }//End of queue empty condition

      int val_recv;

      //Expecting reply from all child processes
      for(int i=0;i<processes_with_files.size();i++){
        MPI::Status status;
        //Probe for incoming values
        MPI::COMM_WORLD.Probe(MPI::ANY_SOURCE, MPI::ANY_TAG, status);
        //Get source and tag
        auto sender = status.Get_source();
        auto tag = status.Get_tag();
        //MPI::Comm::Recv(void* buf, int count, MPI::Datatype& datatype, int source, int tag, MPI::Status* status)
        MPI::COMM_WORLD.Recv(&val_recv, 1, MPI::INT, sender, tag, status);
      }

      while(1){

        int choice;
        string task_message;
        char whatfile[400];

        cout<<"\n\n Graph Processed. What do you want to do now? \n 1. Find all the files related to another file\n 2. Find the Transitive Closure of a file\n 3. Exit\n 4. Choice : ";
        cin>>choice;
        cin.ignore (std::numeric_limits<std::streamsize>::max(), '\n');

        switch(choice) {
          case 1: cout<<"\n Enter the file name : ";
                  cin.getline(whatfile,400);
                  task_message=string(whatfile,strlen(whatfile))+";Related Files";
                  cout<<"\n"<<task_message;
                  break;
          case 2: cout<<"\n Enter the file name you wish to find the transitive closure for : ";
                  cin.getline(whatfile,400);
                  task_message=string(whatfile,strlen(whatfile))+";Transitive Closure;Just Tell";
                  queue_values.insert(whatfile);
                  vec_queue_values.push_back(whatfile);
                  break;
          case 3: task_message="EXIT NOW";

          default:;
        }

        for(int rank_values=1;rank_values<no_of_process;rank_values++){
          //MPI::Comm::Send(const void* buf, int count, MPI::Datatype& datatype, int dest, int tag)
          MPI::COMM_WORLD.Send(task_message.c_str(), task_message.length(), MPI::CHAR, rank_values, rank_values);
        }

        if(choice==3){
          cout<<"\n PARENT : QUITTING. BYE!";
          break;
        }

        else if (choice==2){
          
          int send_flag=1;


          while(send_flag) {


          send_flag=0;

          char* char_value=NULL;
          int char_length;

          // cout<<"\n\n ********************************** Value Sent for Transitive closure!";

          for(int i=0;i<vec_queue_values.size();i++){


            MPI::Status status;
            //Probe for incoming values
            MPI::COMM_WORLD.Probe(MPI::ANY_SOURCE, MPI::ANY_TAG, status);
            //Get source and tag
            char_length = status.Get_count(MPI::CHAR);
            char_value = new char[char_length];
            auto sender = status.Get_source();
            auto tag = status.Get_tag();
            //MPI::Comm::Recv(void* buf, int count, MPI::Datatype& datatype, int source, int tag, MPI::Status* status)
            // cout<<"\n\n Parent waiting to receive!\n\n ";
            MPI::COMM_WORLD.Recv(char_value, char_length, MPI::CHAR, sender, tag, status);
          
          }


          string recd_string(char_value,char_length);
          delete [] char_value;

          vector<string> recd_file_vector;
          string send_string_val="";

          //Clear the vector queue value
          vec_queue_values.clear();

          boost::split(recd_file_vector, recd_string, boost::is_any_of(";"));


          for(int i=0;i<recd_file_vector.size();i++){

            if(recd_file_vector[i].length()){
              
              if(queue_values.find(recd_file_vector[i])==queue_values.end()){
                send_flag=1;
                queue_values.insert(recd_file_vector[i]);
                vec_queue_values.push_back(recd_file_vector[i]);
                send_string_val += recd_file_vector[i] + ";";
              
              }
            }
          }

          send_string_val += "Transitive Closure;Find One";

          if(send_flag){

            for(int rank_values=1;rank_values<no_of_process;rank_values++){  
              // cout<<"\n\n Sending value to "<<rank_values;
               MPI::COMM_WORLD.Send(send_string_val.c_str(), send_string_val.length(), MPI::CHAR, rank_values, rank_values);
            }
          }

          else{
            cout<<"\n\n Connected File Names : \n";
            queue_values.erase(whatfile);
            for(auto x: queue_values){
              cout<<x<<"\n";
            }
            queue_values.clear();
            vec_queue_values.clear();
          }
        }

        }

        else{

          MPI::Status status;
          //Probe for incoming values
          MPI::COMM_WORLD.Probe(MPI::ANY_SOURCE, MPI::ANY_TAG, status);
          //Get source and tag
          auto sender = status.Get_source();
          auto tag = status.Get_tag();
          //MPI::Comm::Recv(void* buf, int count, MPI::Datatype& datatype, int source, int tag, MPI::Status* status)
          // cout<<"\n\n Parent waiting to receive!\n\n ";
          MPI::COMM_WORLD.Recv(&val_recv, 1, MPI::INT, sender, tag, status);
          // cout<<"\n Parent received!";
        }

      } // End of While Loop


    } //END OF PROCESS 0
int main(int argc, char * argv[]){

	int tag, send_tag;//tag in MPI_Recv
        int to,from;//destination and source of MPI send/receive
	int st_count, st_source, st_tag;
	double start_time = 0.0;//set start and end time for MPI_Wtime()
	double end_time = 0.0;
	MPI::Status status;

	MPI::Init(argc, argv);//start MPI
	int rank = MPI::COMM_WORLD.Get_rank();//The rank label of the machines
	int size = MPI::COMM_WORLD.Get_size();//The number of tasks to be done
//	MPI_Barrier(MPI_COMM_WORLD);
	int option;

	opterr = 0;
	int N = 0;
	string directory;

	while ((option = getopt(argc, argv, "d:n:"))!= -1)//getopt parses the parameters of commands, -n is the first n words that occur most frequently in files, -d is the directory which contains the files that need to be parsed.
	{
		switch (option)
		{
			case 'n':
				N = atoi(optarg);//the first N words
			break;
			case 'd':
				directory = string(optarg);// parameter of the directory
//				cout << dir <<endl;
			break;
			case '?'://when the parameter of option n is wrong, show the error information
				if (optopt == 'n')
					cerr<< "Option -"<<char(optopt)<<" requires an argument." <<endl;
			        else if (isprint (optopt))
					cerr<< "Unknown option `-"<<char(optopt)<<"'.\n"<<endl;
				else
					cerr<<  "Unknown option character `"<<std::hex<<optopt<<"'."<<endl;
		}
	}

	vector<string> filenames;//use this vector to store file names
	char buffer[1024];
	
	if(rank == 0)//Machine 0 parses the name of directory and files in the directory.
	{	
		struct dirent *ptr;
		DIR *dir;
		dir = opendir(directory.c_str());//open the directory

		while((ptr = readdir(dir))!=NULL)//read the name of the directory
		{
			if(ptr->d_name[0]=='.')
				continue;
			strcpy(buffer,directory.c_str());
			strcat(buffer,ptr->d_name);
//			cout<<buffer<<endl;
			
			filenames.push_back(string(buffer));//put the file names of the directory in the vector filenames
		};
	}

	if(rank == 0)//machine 0 send messages and assign tasks to all the machines, including itself.
	{
		start_time = MPI_Wtime();//star time stamp
		to = 0;
		send_tag = 0;
		int round = 0;

		while(round * size < filenames.size())
		{
			for(int i = round * size; i < (round + 1) * size && i < filenames.size(); i++)
			{
				sprintf(buffer, "%s", filenames[i].c_str());
				
//				cout << rank << ":"<< "sending " << buffer << endl;
				MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, i%size, send_tag);//send filenames to the other machines and let them parse the files, including itself.
				to++;
				send_tag++;
			}

		
			tag = MPI::ANY_TAG;
			from = MPI::ANY_SOURCE;
			MPI::COMM_WORLD.Recv(buffer, 1024, MPI::CHAR, from, tag, status);//rank 0 receive parsing result from the rest machines, including itself
			st_count = status.Get_count(MPI::CHAR);
			st_source = status.Get_source();
			st_tag = status.Get_tag();
			
			string result("");
			result = parse(buffer, N);
			strcpy(buffer,result.c_str());

			MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, 0, st_tag);//rank 0 send message to itself
			
			for(int i = round * size; i < (round + 1) * size && i < filenames.size(); i++)
			{
				tag = MPI::ANY_TAG;
				from = MPI::ANY_SOURCE;
				MPI::COMM_WORLD.Recv(buffer, 1024, MPI::CHAR, from, tag, status);
				st_count = status.Get_count(MPI::CHAR);
				st_source = status.Get_source();
				st_tag = status.Get_tag();

//				cout << rank <<":" << "received from "<<st_source<<endl<< buffer << endl;
				cout << buffer << endl;
			}

			round++;
		}

		for (int i = 1; i < size; ++i)
		{
			strcpy(buffer, "Finish");
			MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, i, 0);//rank 0 send Finish information to the other machines
		}
		end_time = MPI_Wtime();
		printf("The running time is : %lf \n",end_time-start_time);
	}
	else
	{
		while(1)
		{
			tag = MPI::ANY_TAG;
			from = MPI::ANY_SOURCE;
			MPI::COMM_WORLD.Recv(buffer, 1024, MPI::CHAR, from, tag, status);//receive end information from rank 0
			st_count = status.Get_count(MPI::CHAR);
			st_source = status.Get_source();
			st_tag = status.Get_tag();
//			cout<<" rank " << rank <<": " << "st_count:"<<st_count<<" st_source"<< st_source << " st_tag "<< st_tag << endl;
//			cout<<"         " << buffer <<endl;

			if (strcmp(buffer, "Finish") == 0)//if the machine receives the finish information, stop receive and send
				break;

			string result("");
			result = parse(buffer, N);//parse the file received from rank 0
			strcpy(buffer,result.c_str());

			MPI::COMM_WORLD.Send(buffer,1024, MPI::CHAR, 0, st_tag);//send information back to rank 0
		}
	}

//	cout << "rank " << rank <<": "<<"I am dying, goodbye!"<<endl;
//	MPI_Barrier(MPI_COMM_WORLD);
	MPI::Finalize();//MPI finalize
	return 0;
}
Beispiel #11
0
int main ( int argc, char *argv[] )

//****************************************************************************80
//
//  Purpose:
//
//    MAIN is the main program for SEARCH.
//
//  Discussion:
//
//    SEARCH demonstrates the use of MPI routines to carry out a search
//
//    An array of given size is to be searched for occurrences of a
//    specific value.
//
//    The search is done in parallel.  A master process generates the
//    array and the target value, then distributes the information among
//    a set of worker processes, and waits for them to communicate back
//    the (global) index values at which occurrences of the target value
//    were found.
//
//    An interesting feature of this program is the use of allocatable
//    arrays, which allows the master program to set aside just enough
//    memory for the whole array, and for each worker program to set aside
//    just enough memory for its own part of the array.
//
//  Licensing:
//
//    This code is distributed under the GNU LGPL license. 
//
//  Modified:
//
//    01 September 2009
//
//  Author:
//
//    John Burkardt
//
//  Reference:
//
//    William Gropp, Ewing Lusk, Anthony Skjellum,
//    Using MPI: Portable Parallel Programming with the
//    Message-Passing Interface,
//    Second Edition,
//    MIT Press, 1999,
//    ISBN: 0262571323.
//
{
  int *a;
  int dest;
  float factor;
  int global;
  int i;
  int id;
  int ierr;
  int n;
  int npart;
  int p;
  int source;
  int start;
  MPI::Status status;
  int tag;
  int tag_target = 1;
  int tag_size = 2;
  int tag_data = 3;
  int tag_found = 4;
  int tag_done = 5;
  int target;
  int workers_done;
  int x;
//
//  Initialize MPI.
//
  MPI::Init ( argc, argv );
//
//  Get this processes's rank.
//
  id = MPI::COMM_WORLD.Get_rank ( );
//
//  Find out how many processes are available.
//
  p = MPI::COMM_WORLD.Get_size ( );

  if ( id == 0 )
  {
    timestamp ( );
    cout << "\n";
    cout << "SEARCH - Master process:\n";
    cout << "  C++ version\n";
    cout << "  An example MPI program to search an array.\n";
    cout << "\n";
    cout << "  Compiled on " << __DATE__ << " at " << __TIME__ << ".\n";
    cout << "\n";
    cout << "  The number of processes is " << p << "\n";
  }

  cout << "\n";
  cout << "Process " << id << " is active.\n";
//
//  Have the master process generate the target and data.  In a more 
//  realistic application, the data might be in a file which the master 
//  process would read.  Here, the master process decides.
//
  if ( id == 0 )
  {
//
//  Pick the number of data items per process, and set the total.
//
    factor = ( float ) rand ( ) / ( float ) RAND_MAX;
    npart = 50 + ( int ) ( factor * 100.0E+00 );
    n = npart * p;

    cout << "\n";
    cout << "SEARCH - Master process:\n";
    cout << "  The number of data items per process is " << npart << "\n";
    cout << "  The total number of data items is       " << n << ".\n";
//
//  Now allocate the master copy of A, fill it with values, and pick 
//  a value for the target.
//
    a = new int[n];

    factor = ( float ) n / 10.0E+00 ;

    for ( i = 0; i < n; i++ ) 
    {
      a[i] = ( int ) ( factor * ( float ) rand ( ) / ( float ) RAND_MAX );
    }
    target = a[n/2];

    cout << "  The target value is " << target << ".\n";
//
//  The worker processes need to have the target value, the number of data items,
//  and their individual chunk of the data vector.
//
    for ( i = 1; i <= p-1; i++ )
    {
      dest = i;
      tag = tag_target;

      MPI::COMM_WORLD.Send ( &target, 1, MPI::INT, dest, tag );

      tag = tag_size;

      MPI::COMM_WORLD.Send ( &npart, 1, MPI::INT, dest, tag );

      start = ( i - 1 ) * npart;
      tag = tag_data;

      MPI::COMM_WORLD.Send ( a+start, npart, MPI::INT, dest, tag );
    }
//
//  Now the master process simply waits for each worker process to report that 
//  it is done.
//
    workers_done = 0;

    while ( workers_done < p-1 )
    {
      MPI::COMM_WORLD.Recv ( &x, 1, MPI::INT, MPI::ANY_SOURCE, MPI::ANY_TAG, status );

      source = status.Get_source ( );
      tag = status.Get_tag ( );
    
      if ( tag == tag_done )
      {
        workers_done = workers_done + 1;
      }
      else if ( tag == tag_found )
      {
        cout << "P" << source << "  " << x << "  " << a[x] << "\n";
      }
      else
      {
        cout << "  Master process received message with unknown tag = "
             << tag << ".\n";
      }

    }
//
//  The master process can throw away A now.
//
    delete [] a;
  }
//
//  Each worker process expects to receive the target value, the number of data
//  items, and the data vector.
//
  else 
  {
    source = 0;
    tag = tag_target;

    MPI::COMM_WORLD.Recv ( &target, 1, MPI::INT, source, tag, status );
 
    source = 0;
    tag = tag_size;

    MPI::COMM_WORLD.Recv ( &npart, 1, MPI::INT, source, tag, status );

    a = new int[npart];

    source = 0;
    tag = tag_data;

    MPI::COMM_WORLD.Recv ( a, npart, MPI::INT, source, tag, status );
//
//  The worker simply checks each entry to see if it is equal to the target
//  value.
//
    for ( i = 0; i < npart; i++ )
    {
      if ( a[i] == target )
      {
        global = ( id - 1 ) * npart + i;
        dest = 0;
        tag = tag_found;

        MPI::COMM_WORLD.Send ( &global, 1, MPI::INT, dest, tag );
      }
    }
//
//  When the worker is finished with the loop, it sends a dummy data value with
//  the tag "TAG_DONE" indicating that it is done.
//
    dest = 0;
    tag = tag_done;

    MPI::COMM_WORLD.Send ( &target, 1, MPI::INT, dest, tag );

    delete [] ( a );
     
  }
//
//  Terminate MPI.
//
  MPI::Finalize ( );
//
//  Terminate.
//
  if ( id == 0 )
  {
    cout << "\n";
    cout << "SEARCH - Master process:\n";
    cout << "  Normal end of execution.\n";
    cout << "\n";
    timestamp ( );
  } 
  return 0;
}
template<class T_GRID> int FLOOD_FILL_MPI<T_GRID>::
Synchronize_Colors()
{
    if(mpi_grid.threaded_grid) return Synchronize_Colors_Threaded();
    ARRAY<RANGE<typename T_PARALLEL_GRID::VECTOR_INT> > boundary_regions;
    mpi_grid.Find_Boundary_Regions(boundary_regions,RANGE<typename T_PARALLEL_GRID::VECTOR_INT>::Zero_Box(),false,RANGE<VECTOR<int,1> >(-1,0),false,true,local_grid);
    // figure out which colors are global
    int global_color_count=0;
    ARRAY<int,VECTOR<int,1> > color_map(-1,number_of_regions);color_map(-1)=-1;color_map(0)=0;
    {ARRAY<bool,VECTOR<int,1> > color_is_global(-1,number_of_regions);
    Find_Global_Colors(color_is_global,RANGE<typename T_PARALLEL_GRID::VECTOR_INT>::Centered_Box());
    for(int color=1;color<=number_of_regions;color++)if(color_is_global(color)) color_map(color)=++global_color_count;}

    // send numbers of global colors to everyone
    ARRAY<int> global_color_counts(mpi_grid.number_of_processes);
    mpi_grid.comm->Allgather(&global_color_count,1,MPI_UTILITIES::Datatype<int>(),&global_color_counts(1),1,MPI_UTILITIES::Datatype<int>());
    int total_global_colors=ARRAYS_COMPUTATIONS::Sum(global_color_counts);
    int global_color_offset=ARRAYS_COMPUTATIONS::Sum(global_color_counts.Prefix(mpi_grid.rank));
    LOG::cout<<"initial colors: "<<number_of_regions<<" total, "<<global_color_count<<" out of "<<total_global_colors<<" global"<<std::endl;
    if(!total_global_colors){color_ranks.Clean_Memory();return 0;}

    ARRAY<MPI_PACKAGE> packages;
    ARRAY<T_ARRAYS_INT> colors_copy(boundary_regions.m);
    // send left (front) colors
    ARRAY<MPI::Request> send_requests;
    for(int side=1;side<=T_PARALLEL_GRID::number_of_faces_per_cell;side+=2)if(mpi_grid.side_neighbor_ranks(side)!=MPI::PROC_NULL){
        Resize_Helper(colors_copy(side),local_grid,boundary_regions(side));
        Translate_Local_Colors_To_Global_Colors(color_map,colors_copy(side),boundary_regions(side),global_color_offset);
        MPI_PACKAGE package=mpi_grid.Package_Cell_Data(colors_copy(side),boundary_regions(side));
        packages.Append(package);
        send_requests.Append(package.Isend(*mpi_grid.comm,mpi_grid.side_neighbor_ranks(side),mpi_grid.Get_Send_Tag(mpi_grid.side_neighbor_directions(side))));}
    // receive right (back) colors and initialize union find
    UNION_FIND<> union_find(total_global_colors);
    {ARRAY<MPI::Request> recv_requests;
    for(int side=2;side<=T_PARALLEL_GRID::number_of_faces_per_cell;side+=2)if(mpi_grid.side_neighbor_ranks(side)!=MPI::PROC_NULL){
        Resize_Helper(colors_copy(side),local_grid,boundary_regions(side));
        MPI_PACKAGE package=mpi_grid.Package_Cell_Data(colors_copy(side),boundary_regions(side));
        packages.Append(package);
        recv_requests.Append(package.Irecv(*mpi_grid.comm,mpi_grid.side_neighbor_ranks(side),mpi_grid.Get_Recv_Tag(mpi_grid.side_neighbor_directions(side))));}
    MPI::Status status;
    while(MPI_UTILITIES::Wait_Any(recv_requests,status)){
        int side;for(side=2;side<=T_PARALLEL_GRID::number_of_faces_per_cell;side+=2)if(mpi_grid.Get_Recv_Tag(mpi_grid.side_neighbor_directions(side))==status.Get_tag()) break;
        Find_Color_Matches(color_map,union_find,colors_copy(side),boundary_regions(side),global_color_offset);}}

    // synchronize union find
    UNION_FIND<> final_union_find;
    {ARRAY<char> union_find_buffer(MPI_UTILITIES::Pack_Size(union_find,*mpi_grid.comm)+1);
    {int position=0;MPI_UTILITIES::Pack(union_find,union_find_buffer,position,*mpi_grid.comm);}
    MPI::Datatype union_find_type=MPI::PACKED.Create_contiguous(union_find_buffer.m);union_find_type.Commit();
    MPI::Op union_find_merge_op;union_find_merge_op.Init(Union_Find_Merge_Op,true);
    ARRAY<char> final_union_find_buffer(union_find_buffer.m);
    union_find_merge_op_comm=mpi_grid.comm;
    mpi_grid.comm->Allreduce(union_find_buffer.Get_Array_Pointer(),final_union_find_buffer.Get_Array_Pointer(),1,union_find_type,union_find_merge_op);
    {int position=0;MPI_UTILITIES::Unpack(final_union_find,final_union_find_buffer,position,*mpi_grid.comm);}
    union_find_type.Free();union_find_merge_op.Free();}

    // fix color map for global colors
    number_of_regions=0;
    ARRAY<int> global_to_final_color_map(total_global_colors);
    for(int i=1;i<=total_global_colors;i++){
        int root=final_union_find.Find(i);
        if(!global_to_final_color_map(root)) global_to_final_color_map(root)=++number_of_regions;
        global_to_final_color_map(i)=global_to_final_color_map(root);}
    for(int i=1;i<=color_map.domain.max_corner.x;i++)if(color_map(i)>0) color_map(i)=global_to_final_color_map(color_map(i)+global_color_offset);

    // find list of processes corresponding to each color
    int end=0;
    color_ranks.Clean_Memory();
    color_ranks.Resize(number_of_regions);
    for(int r=0;r<mpi_grid.number_of_processes;r++){
        int start=end+1;end+=global_color_counts(r+1);
        for(int i=start;i<=end;i++)color_ranks(global_to_final_color_map(i)).Append_Unique(r);}
    for(int color=1;color<=color_ranks.m;color++) assert(color_ranks(color).m>1 || mpi_grid.side_neighbor_ranks.Contains(mpi_grid.rank));

    // remap colors
    Remap_Colors(color_map,RANGE<typename T_PARALLEL_GRID::VECTOR_INT>::Centered_Box());

    LOG::cout<<"final colors: "<<color_ranks.m<<" global, "<<number_of_regions-color_ranks.m<<" local"<<std::endl;

    // remap color_touches_uncolorable
    if(color_touches_uncolorable){
        ARRAY<bool> new_color_touches_uncolorable(number_of_regions);
        for(int i=1;i<=color_touches_uncolorable->m;i++)if(color_map(i)>0) new_color_touches_uncolorable(color_map(i))|=(*color_touches_uncolorable)(i);
        color_touches_uncolorable->Exchange(new_color_touches_uncolorable);
        // synchronize color_touches_uncolorable, TODO: this could be merged with above communication
        ARRAY<bool> global_color_touches_uncolorable(color_ranks.m);
        ARRAY<bool>::Get(global_color_touches_uncolorable,*color_touches_uncolorable);
        mpi_grid.comm->Allreduce(&global_color_touches_uncolorable(1),&(*color_touches_uncolorable)(1),color_ranks.m,MPI_UTILITIES::Datatype<bool>(),MPI::LOR);}

    // finish
    MPI_UTILITIES::Wait_All(send_requests);
    MPI_PACKAGE::Free_All(packages);

    return color_ranks.m;
}