#include "serial_gs_pagerank_functions.h" const char *ARGUMENT_CONVERGENCE_TOLERANCE = "-c"; const char *ARGUMENT_MAX_ITERATIONS = "-m"; const char *ARGUMENT_DAMPING_FACTOR = "-a"; const char *ARGUMENT_VERBAL_OUTPUT = "-v"; const char *ARGUMENT_OUTPUT_HISTORY = "-h"; const char *ARGUMENT_OUTPUT_FILENAME = "-o"; const int NUMERICAL_BASE = 10; char *DEFAULT_OUTPUT_FILENAME = "pagerank_output"; // ==================== PAGERANK ==================== int pagerank(double ***transitionMatrix, double **pagerankVector, Parameters parameters) { int iterations = 0; double delta, *vectorDifference = (double *) malloc(parameters.numberOfPages * sizeof(double)), *previousPagerankVector = (double *) malloc(parameters.numberOfPages * sizeof(double)), *convergedPagerankVector = (double *) malloc(parameters.numberOfPages * sizeof(double)); for (int i=0; i parameters.convergenceCriterion && (parameters.maxIterations == 0 || iterations < parameters.maxIterations)); if (!parameters.history) { savePagerankToFile(parameters.outputFilename, false, *pagerankVector, parameters.numberOfPages); } return iterations; } // ==================== INITIALIZATION ==================== /* * initialize allocates required memory for arrays, reads the web graph from the * from the file and creates the initial transition probability distribution * matrix. */ void initialize(int ***directedWebGraph, double ***transitionMatrix, double **pagerankVector, Parameters *parameters) { // Reads web graph from file if ((*parameters).verbose) { printf("----- Reading graph from file -----\n"); } readGraphFromFile(directedWebGraph, parameters); // Outputs the algorithm parameters to the console if ((*parameters).verbose) { printf("\n----- Running with parameters -----\ \nNumber of pages: %d", (*parameters).numberOfPages); if (!(*parameters).maxIterations) { printf("\nMaximum number of iterations: inf"); } else { printf("\nMaximum number of iterations: %d", (*parameters).maxIterations); } printf("\nConvergence criterion: %f\ \nDamping factor: %f\ \nGraph filename: %s\n", (*parameters).convergenceCriterion, (*parameters).dampingFactor, (*parameters).graphFilename); } // Allocates memory for the pagerank vector (*pagerankVector) = (double *) malloc((*parameters).numberOfPages * sizeof(double)); double webUniformProbability = 1. / (*parameters).numberOfPages; for (int i=0; i<(*parameters).numberOfPages; ++i) { (*pagerankVector)[i] = webUniformProbability; } // Generates the initial transition matrix (matrix P). generateNormalizedTransitionMatrix(transitionMatrix, *directedWebGraph, *parameters); // Transposes the transition matrix (P^T). transposeMatrix(transitionMatrix, (*parameters).numberOfPages, (*parameters).numberOfPages); } /* * generateNormalizedTransitionMatrix generates the normalized transition matrix * from the graph data (matrix P'). */ void generateNormalizedTransitionMatrix(double ***transitionMatrix, int **directedWebGraph, Parameters parameters) { // Allocates memory for the transitionMatrix rows (*transitionMatrix) = (double **) malloc(parameters.numberOfPages * sizeof(double *)); for (int i=0; i 10) { validUsage(argumentVector[0]); } (*parameters).numberOfPages = 0; (*parameters).maxIterations = 0; (*parameters).convergenceCriterion = 1; (*parameters).dampingFactor = 0.85; (*parameters).verbose = false; (*parameters).history = false; (*parameters).outputFilename = DEFAULT_OUTPUT_FILENAME; char *endPointer; int argumentIndex = 1; while (argumentIndex < argumentCount) { if (!strcmp(argumentVector[argumentIndex], ARGUMENT_CONVERGENCE_TOLERANCE)) { argumentIndex = checkIncrement(argumentIndex, argumentCount, argumentVector[0]); double convergenceInput = strtod(argumentVector[argumentIndex], &endPointer); if (convergenceInput == 0) { printf("Invalid convergence argument\n"); exit(EXIT_FAILURE); } (*parameters).convergenceCriterion = convergenceInput; } else if (!strcmp(argumentVector[argumentIndex], ARGUMENT_MAX_ITERATIONS)) { argumentIndex = checkIncrement(argumentIndex, argumentCount, argumentVector[0]); size_t iterationsInput = strtol(argumentVector[argumentIndex], &endPointer, NUMERICAL_BASE); if (iterationsInput == 0 && endPointer) { printf("Invalid iterations argument\n"); exit(EXIT_FAILURE); } (*parameters).maxIterations = iterationsInput; } else if (!strcmp(argumentVector[argumentIndex], ARGUMENT_DAMPING_FACTOR)) { argumentIndex = checkIncrement(argumentIndex, argumentCount, argumentVector[0]); double alphaInput = strtod(argumentVector[argumentIndex], &endPointer); if ((alphaInput == 0 || alphaInput > 1) && endPointer) { printf("Invalid alpha argument\n"); exit(EXIT_FAILURE); } (*parameters).dampingFactor = alphaInput; } else if (!strcmp(argumentVector[argumentIndex], ARGUMENT_VERBAL_OUTPUT)) { (*parameters).verbose = true; } else if (!strcmp(argumentVector[argumentIndex], ARGUMENT_OUTPUT_HISTORY)) { (*parameters).history = true; } else if (!strcmp(argumentVector[argumentIndex], ARGUMENT_OUTPUT_FILENAME)) { argumentIndex = checkIncrement(argumentIndex, argumentCount, argumentVector[0]); if (fopen(argumentVector[argumentIndex], "w") == NULL) { printf("Invalid output filename. Reverting to default.\n"); continue; } (*parameters).outputFilename = argumentVector[argumentIndex]; } else if (argumentIndex == argumentCount - 1) { (*parameters).graphFilename = argumentVector[argumentIndex]; } else { validUsage(argumentVector[0]); exit(EXIT_FAILURE); } ++argumentIndex; } } /* * readGraphFromFile loads the file supplied in the command line arguments to an * array (directedWebGraph) that represents the graph. */ void readGraphFromFile(int ***directedWebGraph, Parameters *parameters) { FILE *graphFile; // Opens the file for reading graphFile = fopen((*parameters).graphFilename, "r+"); if (!graphFile) { printf("Error opening file \n"); exit(EXIT_FAILURE); } // Reads the dimensions of the (square) array from the file int readChar, numberOfLines=0; while((readChar = fgetc(graphFile))) { // Breaks if end of file if (readChar == EOF) break; // Otherwise, if the character is a break line, adds one to the count of lines if (readChar == '\n') { ++numberOfLines; } } if ((*parameters).verbose) { printf("Line count of file is %d \n", numberOfLines + 1); } // Each line of the file represents one page of the graph (*parameters).numberOfPages = numberOfLines + 1; rewind(graphFile); // Allocates memory and loads values into directedWebGraph (matrix A) // Allocates memory for the rows (*directedWebGraph) = (int **) malloc((*parameters).numberOfPages * sizeof(int *)); for (int i=0; i<(*parameters).numberOfPages; ++i) { // Allocates memory for the columns of this row (*directedWebGraph)[i] = (int *) malloc((*parameters).numberOfPages * sizeof(int)); // Reads values from the file for (int j=0; j<(*parameters).numberOfPages; ++j) { if (!fscanf(graphFile, "%d ", &(*directedWebGraph)[i][j])) { break; } } } fclose(graphFile); } /* * validUsage outputs a message to the console that informs the user of the * correct (valid) way to use the program. */ void validUsage(char *programName) { printf("%s [-c convergence_criterion] [-m max_iterations] [-a alpha] [-v] [-h] [-o output_filename] \ \n-c convergence_criterion\ \n\tthe convergence tolerance criterion\ \n-m max_iterations\ \n\tmaximum number of iterations to perform\ \n-a alpha\ \n\tthe damping factor\ \n-v enable verbal output\ \n-h enable history output to file\ \n-o output_filename\ \n\tfilename and path for the output\ \n", programName); exit(EXIT_FAILURE); } /* * checkIncrement is a helper function for parseArguments function. */ int checkIncrement(int previousIndex, int maxIndex, char *programName) { if (previousIndex == maxIndex) { validUsage(programName); exit(EXIT_FAILURE); } return ++previousIndex; } void savePagerankToFile(char *filename, bool append, double *pagerankVector, int vectorSize) { FILE *outputFile; if (append) { outputFile = fopen(filename, "a"); } else { outputFile = fopen(filename, "w"); } if (outputFile == NULL) { printf("Error while opening the output file.\n"); return; } for (int i=0; i