#include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* 8-Byte numbers in 256KB = 32768 8-Byte numbers in 1MB = 131072 8-Byte numbers in 1GB = 134217728 All the programm assume numbers as 64_bits. To visualize binary files in bash can be used: od -t d8 -A n binaryfile.bin #For in use format od -t d8 -A n --endian=little binaryfile.bin #For little-endian format od -t d8 -A n --endian=big binaryfile.bin #For big-endian format */ #define BUFFERSIZE 32768 #define CACHENUM 130000 #define RAMNUM 268435456 #define ALLOW_BUFFER 1 #define ALLOW_SNOWPLOW 1 void sortRuns(unsigned long long fileSize, unsigned long long sliceSize, unsigned long long maxLoop, FILE* file, int id, int mpiRank, int mpiSize) { unsigned long long startOffset, endOffset, currentOffset; //The interval is [startOffset, endOffset) double startTot, start, end; int64_t num; std::vector bigVect; int64_t buffer[BUFFERSIZE]; bigVect.reserve(sliceSize); startTot = MPI_Wtime(); //Microsecond precision. Can't use time(), because each process will have a different "zero" time start = MPI_Wtime(); for(unsigned long long l = 0; l < maxLoop; l++) //Populate the vector with the values in the file { startOffset = sliceSize * (mpiRank + (mpiSize * l)); if (startOffset >= fileSize) break; endOffset = startOffset + sliceSize; fseek(file, startOffset * sizeof(int64_t), SEEK_SET); currentOffset = startOffset; bigVect.clear(); if (ALLOW_BUFFER) //Branch to test performance with and without buffer { while (currentOffset < endOffset) { unsigned long long elementsToRead = std::min(endOffset - currentOffset, static_cast(BUFFERSIZE)); //It's important to check because if the difference between endOffset and startOffset is smaller than BUFFERSIZE we don't have to read further unsigned long long elementsRead = fread(buffer, sizeof(int64_t), elementsToRead, file); for (unsigned long long i = 0; i < elementsRead; ++i) { bigVect.push_back(buffer[i]); } currentOffset += elementsRead; //Increment currentOffset based on the number of elements read if (elementsRead < BUFFERSIZE) // Check if we have reached the end of the file break; } } else { while (currentOffset < endOffset && fread(&num, sizeof(int64_t), 1, file) == 1) { bigVect.push_back(num); currentOffset++; } } end = MPI_Wtime(); std::cout << " " << end-start << "s" << " => Time to read file from offset " << startOffset << " to " << endOffset << " in Process " << mpiRank+1 << "/" << mpiSize << " memory" << std::endl; start = MPI_Wtime(); sort(bigVect.begin(), bigVect.end()); end = MPI_Wtime(); std::cout << " " << end-start << "s" << " => Time to sort elements in Process " << mpiRank+1 << "/" << mpiSize << " memory" << std::endl; start = MPI_Wtime(); std::string templateName = "/mnt/raid/tmp/SortedRun" + std::to_string(id) + "_XXXXXX"; //If absolute path does not exist the temporary file will not be created int tmpFile = mkstemp(&templateName[0]); //Create a temporary file based on template if (tmpFile == -1) { std::cout << "Error creating temporary file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } for (unsigned long long i = 0; i < bigVect.size(); ++i) //Write the ordered number in a temp file { if (ALLOW_BUFFER) //Branch to test performance with and without buffer { buffer[i % BUFFERSIZE] = bigVect[i]; if ((i + 1) % BUFFERSIZE == 0 || i == bigVect.size() - 1) { ssize_t tw = write(tmpFile, buffer, sizeof(int64_t) * ((i % BUFFERSIZE) + 1)); if (tw == -1) { std::cout << "Error writing to file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } } else { int64_t elem = bigVect[i]; ssize_t tw = write(tmpFile, &elem, sizeof(int64_t)); if (tw == -1) { std::cout << "Error writing to file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } } off_t sz = lseek(tmpFile, 0, SEEK_END); if (sz == 0) { if (close(tmpFile) == -1) { std::cout << "Error closing the file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } if (unlink(&templateName[0]) == -1) { std::cout << "Error unlinking file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } if (close(tmpFile) == -1) { std::cout << "Error closing the file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } end = MPI_Wtime(); std::cout << " " << end-start << "s" << " => Time to write '" << templateName << "' and fill it up with " << sz/8 << " sorted elements by Process " << mpiRank+1 << "/" << mpiSize << std::endl; start = MPI_Wtime(); } end = MPI_Wtime(); std::cout << end-startTot << "s" << " => Time function sortRuns() in Process " << mpiRank+1 << "/" << mpiSize << std::endl; } void snowPlowRuns(unsigned long long fileSize, unsigned long long sliceSize, unsigned long long maxLoop, FILE* file, int id, int mpiRank, int mpiSize) { if (ALLOW_SNOWPLOW) std::cout << "Can't compute files of size bigger then " << RAMNUM * mpiSize / 134217728 << "Gb with " << mpiSize << " processes (currently file is " << fileSize / 134217728 << "Gb)" << std::endl; else { maxLoop = (fileSize / (RAMNUM * mpiSize)) + 1; sortRuns(fileSize, RAMNUM, maxLoop, file, id, mpiRank, mpiSize); } } void kMerge(const std::string &argFile, int id, int mpiRank, int mpiSize) { std::string fileDir = "/mnt/raid/tmp/"; std::string pattern = "SortedRun" + std::to_string(id) + "_"; std::vector fds; //To store the file descriptor of each file to merge std::vector fns; //To store the file name of each file to delete after merge size_t lastSlash = argFile.find_last_of('/'); std::string nameOnly = (lastSlash != std::string::npos) ? argFile.substr(lastSlash + 1) : argFile; std::string finalFile = "/mnt/raid/tmp/" + nameOnly + (ALLOW_BUFFER == 1 ? ".buf" : "") + ".sort"; double start, end; int fileCount = 0; DIR *dir = opendir(fileDir.c_str()); if (dir) { struct dirent *entry; while ((entry = readdir(dir)) != nullptr) { if (entry->d_type == DT_REG) //Check if it's a regular file { std::string filename = entry->d_name; if (filename.find(pattern) != std::string::npos) //Check if the file name matches the pattern { std::string tmpFile = fileDir + "/" + filename; int fd = open(tmpFile.c_str(), O_RDONLY); //Open the file and save the file descriptor if (fd != -1) { fds.push_back(fd); fns.push_back(tmpFile); fileCount++; } else std::cout << "Error opening file '" << tmpFile << "' by Process " << mpiRank+1 << "/" << mpiSize << std::endl; } } } closedir(dir); } else { std::cout << "Error opening directory '" << fileDir << "' by Process " << mpiRank+1 << "/" << mpiSize << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } int fdFinal = open(finalFile.c_str(), O_WRONLY | O_CREAT | O_EXCL, S_IRUSR | S_IWUSR); //Open the file for writing only, creating it if it doesn't exist and not overwrite if it exists if (fdFinal == -1) { std::cout << "Error opening or creating final file '" << finalFile << "' by Process " << mpiRank+1 << "/" << mpiSize << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } std::cout << std::endl << "Starting the merge process for " << fileCount << " files" << std::endl << std::endl; start = MPI_Wtime(); std::priority_queue, std::vector>, std::greater>> minHeap; //Creating a Min Heap using a priority queue int64_t tmpValue; for (int fd : fds) //Populate the Min Heap with initial values from each file descriptor { if (read(fd, &tmpValue, sizeof(int64_t)) == sizeof(int64_t)) minHeap.push({tmpValue, fd}); else { std::cout << "Error reading from file descriptor by Process " << mpiRank+1 << "/" << mpiSize << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } int tmpfd; int64_t tmpValue2; int64_t buffer[BUFFERSIZE]; unsigned long long i = 0; while (!minHeap.empty()) //Write sorted elements to the temporary file { tmpValue = minHeap.top().first; tmpfd = minHeap.top().second; if (read(tmpfd, &tmpValue2, sizeof(int64_t)) == sizeof(int64_t)) //Read another integer from the same file descriptor { minHeap.pop(); minHeap.push({tmpValue2, tmpfd}); } else //If no more values can be read { minHeap.pop(); if (close(tmpfd) == -1) { std::cout << "Error closing the file descriptor by Process " << mpiRank+1 << "/" << mpiSize << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } if (ALLOW_BUFFER) //Branch to test performance with and without buffer { buffer[i % BUFFERSIZE] = tmpValue; if ((i + 1) % BUFFERSIZE == 0 || minHeap.empty()) { ssize_t tw = write(fdFinal, buffer, sizeof(int64_t) * ((i % BUFFERSIZE) + 1)); if (tw == -1) { std::cout << "Error writing to file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } i++; } else { ssize_t tw = write(fdFinal, &tmpValue, sizeof(int64_t)); if (tw == -1) { std::cout << "Error writing to file" << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } } for (const std::string &fn : fns) //Remove all temporary files after merging them { if (unlink(&fn[0]) == -1) { std::cout << "Error unlinking file '" << fn << "' by Process " << mpiRank+1 << "/" << mpiSize << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } } end = MPI_Wtime(); std::cout << end-start << "s" << " => Time function kMerge() in Process " << mpiRank+1 << "/" << mpiSize << std::endl; std::cout << std::endl << "Sorted file '" << finalFile << "'" << std::endl; } int main(int argc, char* argv[]) { MPI_Init(&argc, &argv); //Initialize the MPI environment double startGlobal, endGlobal; int id, mpiSize, mpiRank; MPI_Comm_size(MPI_COMM_WORLD, &mpiSize); //Get the number of processes MPI_Comm_rank(MPI_COMM_WORLD, &mpiRank); //Get the number of process if (mpiRank == 0) { startGlobal = MPI_Wtime(); std::srand(std::time(0)); id = std::rand() % 10000; //Get a random id number to recognize files of different executions } MPI_Bcast(&id, 1, MPI_INT, 0, MPI_COMM_WORLD); if (argc != 2) { if (mpiRank == 0) { std::cout << "Usage: " << argv[0] << " " << std::endl; std::cout << "It returns a file with extension '.sort' in the same directory of the not-parsed one. Make sure to have space before." << std::endl; std::cout << "Use arguments in the make as ARGS=\"stuff\". Example 'make run ARGS=\"/path/to/file\"'." << std::endl; } MPI_Finalize(); //Clean up the MPI environment return 0; } FILE *file; unsigned long long fileSize, slices, sliceSize, maxLoop; file = fopen(argv[1], "rb"); //Open the file in mode rb (read binary) if(!file) { std::cout << "Error opening file: " << argv[1] << std::endl; MPI_Abort(MPI_COMM_WORLD, 1); } fseek(file,0,SEEK_END); fileSize = ftell(file) / 8; //Size in bytes of the file, correspond to the number of numbers to parse. Each number is 8 bytes if (mpiRank == 0) std::cout << "Sorting file '" << argv[1] << "' of " << fileSize << " elements" << std::endl << std::endl; if (fileSize < (CACHENUM * mpiSize)) slices = (fileSize / CACHENUM) + 1; else if (fileSize < (RAMNUM * mpiSize)) //TODO add more granularity considering double RAM for snow plow technique slices = (fileSize / RAMNUM) + 1; else slices = mpiSize + 1; sliceSize = (fileSize / slices) + 1; //Each process divides a number of 8-byte integers based on the size of the starting file, Attualmente dentro create Runs maxLoop = (slices / mpiSize) + 1; if (sliceSize > RAMNUM) snowPlowRuns(fileSize, sliceSize, maxLoop, file, id, mpiRank, mpiSize); else sortRuns(fileSize, sliceSize, maxLoop, file, id, mpiRank, mpiSize); fclose(file); MPI_Barrier(MPI_COMM_WORLD); //Blocks the caller until all processes in the communicator have called it if(mpiRank==0) { kMerge(argv[1], id, mpiRank, mpiSize); endGlobal = MPI_Wtime(); std::cout << (endGlobal-startGlobal)/60.0 << "min" << " => FULL EXECUTION TIME" << std::endl; std::cout << std::endl << "To visualize binary files in bash can be used:" << std::endl; std::cout << "od -t d8 -A n binaryfile.bin #For in use format" << std::endl; std::cout << "od -t d8 -A n --endian=little binaryfile.bin #For little-endian format" << std::endl; std::cout << "od -t d8 -A n --endian=big binaryfile.bin #For big-endian format" << std::endl; } MPI_Finalize(); //Clean up the MPI environment return 0; }