#include "exports.hpp" #include "graph.hpp" #include "graph_ccm.hpp" #include "graph_powerlaw.hpp" #include "switchchain.hpp" #include #include #include #include #include #include int main(int argc, char* argv[]) { // Simulation parameters const int numVerticesMin = 1000; const int numVerticesMax = 1000; const int numVerticesStep = 500; //float tauValues[] = {2.1f, 2.2f, 2.3f, 2.4f, 2.5f, 2.6f, 2.7f, 2.8f, 2.9f}; float tauValues[] = {2.1f, 2.5f, 2.9f}; const int totalDegreeSamples = 5000; const int ccmConstructionAttemps = 200; // Output file std::ofstream outfile; if (argc >= 2) outfile.open(argv[1]); else outfile.open("graphdata_ccm_constructionrate.m"); if (!outfile.is_open()) { std::cout << "ERROR: Could not open output file.\n"; return 1; } // Output Mathematica-style comment to indicate file contents outfile << "(*\n"; outfile << "n from " << numVerticesMin << " to " << numVerticesMax << " step " << numVerticesStep << std::endl; outfile << "tauValues: " << tauValues << std::endl; outfile << "degreeSamples: " << totalDegreeSamples << std::endl; outfile << "mixingTime: -\n"; outfile << "measurements: -\n"; outfile << "measureSkip: -\n"; outfile << "ccm construction attemps: " << ccmConstructionAttemps << std::endl; outfile << "data:\n"; outfile << "1: {n,tau}\n"; outfile << "3: CCMdu construction rate \n"; outfile << "4: CCMd construction rate \n"; outfile << "*)" << std::endl; // Mathematica does not accept normal scientific notation outfile << std::fixed; outfile << '{'; bool outputComma = false; std::mt19937 rng(std::random_device{}()); Graph g; for (int numVertices = numVerticesMin; numVertices <= numVerticesMax; numVertices += numVerticesStep) { for (float tau : tauValues) { // For a single n,tau take samples over several instances of // the degree distribution. for (int degreeSample = 0; degreeSample < totalDegreeSamples; ++degreeSample) { DegreeSequence ds; generatePowerlawGraph(numVertices, tau, g, ds, rng); std::cout << "Running (n,tau) = (" << numVertices << ',' << tau << "). " << std::flush; // // Test the GCM1 and GCM2 success rate // int successrate1 = 0; int successrate2 = 0; for (int i = 0; i < ccmConstructionAttemps; ++i) { Graph gtemp; // Take new highest degree every time if (constrainedConfigurationModel(ds, gtemp, rng, false)) { ++successrate1; } // Finish all pairings of highest degree first if (constrainedConfigurationModel(ds, gtemp, rng, true)) { ++successrate2; } } std::cout << "Done." << std::flush; if (outputComma) outfile << ',' << '\n'; outputComma = true; outfile << '{'; outfile << '{' << numVertices << ',' << tau << '}'; outfile << ',' << float(successrate1)/float(ccmConstructionAttemps); outfile << ',' << float(successrate2)/float(ccmConstructionAttemps); outfile << '}' << std::flush; std::cout << std::endl; } } } outfile << '}'; return 0; }