/***************************************************************************************[MultiSolvers.h] Glucose -- Copyright (c) 2009-2014, Gilles Audemard, Laurent Simon CRIL - Univ. Artois, France LRI - Univ. Paris Sud, France (2009-2013) Labri - Univ. Bordeaux, France Syrup (Glucose Parallel) -- Copyright (c) 2013-2014, Gilles Audemard, Laurent Simon CRIL - Univ. Artois, France Labri - Univ. Bordeaux, France Glucose sources are based on MiniSat (see below MiniSat copyrights). Permissions and copyrights of Glucose (sources until 2013, Glucose 3.0, single core) are exactly the same as Minisat on which it is based on. (see below). Glucose-Syrup sources are based on another copyright. Permissions and copyrights for the parallel version of Glucose-Syrup (the "Software") are granted, free of charge, to deal with the Software without restriction, including the rights to use, copy, modify, merge, publish, distribute, sublicence, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: - The above and below copyrights notices and this permission notice shall be included in all copies or substantial portions of the Software; - The parallel version of Glucose (all files modified since Glucose 3.0 releases, 2013) cannot be used in any competitive event (sat competitions/evaluations) without the express permission of the authors (Gilles Audemard / Laurent Simon). This is also the case for any competitive event using Glucose Parallel as an embedded SAT engine (single core or not). --------------- Original Minisat Copyrights Copyright (c) 2003-2006, Niklas Een, Niklas Sorensson Copyright (c) 2007-2010, Niklas Sorensson Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. **************************************************************************************************/ #ifndef MultiSolvers_h #define MultiSolvers_h #include "parallel/ParallelSolver.h" namespace Glucose { class SolverConfiguration; class MultiSolvers { friend class SolverConfiguration; public: MultiSolvers(ParallelSolver *s); MultiSolvers(); ~MultiSolvers(); void printFinalStats(); void setVerbosity(int i); int verbosity(); void setVerbEveryConflicts(int i); void setShowModel(int i) {showModel = i;} int getShowModel() {return showModel;} // Problem specification: // Var newVar (bool polarity = true, bool dvar = true); // Add a new variable with parameters specifying variable mode. bool addClause (const vec& ps); // Add a clause to the solver. NOTE! 'ps' may be shrunk by this method! bool addClause_( vec& ps); bool simplify (); // Removes already satisfied clauses. int nVars () const; // The current number of variables. int nClauses () const; // The current number of variables. ParallelSolver *getPrimarySolver(); void generateAllSolvers(); // Solving: // lbool solve (); // Search without assumptions. bool eliminate(); // Perform variable elimination void adjustParameters(); void adjustNumberOfCores(); void interrupt() {} vec model; // If problem is satisfiable, this vector contains the model (if any). inline bool okay() { if(!ok) return ok; for(int i = 0;iokay()) { ok = false; return false; } } return true; } bool use_simplification; protected: friend class ParallelSolver; friend class SolverCompanion; struct Stats { uint64_t min, max, avg, std, med; Stats(uint64_t _min = 0,uint64_t _max = 0,uint64_t _avg = 0,uint64_t _std = 0,uint64_t _med = 0) : min(_min), max(_max), avg(_avg), std(_std), med(_med) {} }; void printStats(); int ok; lbool result; int maxnbthreads; // Maximal number of threads int nbthreads; // Current number of threads int nbsolvers; // Number of CDCL solvers int nbcompanions; // Number of companions int nbcompbysolver; // Number of companions by solvers bool immediateSharingGlue ; int allClonesAreBuilt; bool showModel; // show model on/off int winner; vec add_tmp; double var_decay; // Inverse of the variable activity decay factor. (default 1 / 0.95) double clause_decay; // Inverse of the clause activity decay factor. (1 / 0.999) double cla_inc; // Amount to bump next clause with. double var_inc; // Amount to bump next variable with. double random_var_freq; // The frequency with which the decision heuristic tries to choose a random variable. (default 0.02) int restart_first; // The initial restart limit. (default 100) double restart_inc; // The factor with which the restart limit is multiplied in each restart. (default 1.5) double learntsize_factor; // The intitial limit for learnt clauses is a factor of the original clauses. (default 1 / 3) double learntsize_inc; // The limit for learnt clauses is multiplied with this factor each restart. (default 1.1) bool expensive_ccmin; // Controls conflict clause minimization. (default TRUE) int polarity_mode; // Controls which polarity the decision heuristic chooses. See enum below for allowed modes. (default polarity_false) unsigned int maxmemory; unsigned int maxnbsolvers; int verb; int verbEveryConflicts; int numvar; // Number of variables int numclauses; // Number of clauses enum { polarity_true = 0, polarity_false = 1, polarity_user = 2, polarity_rnd = 3 }; //ClauseAllocator ca; SharedCompanion * sharedcomp; void informEnd(lbool res); ParallelSolver* retrieveSolver(int i); pthread_mutex_t m; // mutex for any high level sync between all threads (like reportf) pthread_mutex_t mfinished; // mutex on which main process may wait for... As soon as one process finishes it release the mutex pthread_cond_t cfinished; // condition variable that says that a thread has finished vec solvers; // set of plain solvers vec solvercompanions; // set of companion solvers vec threads; // all threads of this process vec threadIndexOfSolver; // threadIndexOfSolver[solvers[i]] is the index in threads[] of the solver i vec threadIndexOfSolverCompanion; // threadIndexOfSolverCompanion[solvercompanions[i]] is the index in threads[] of the solvercompanion i }; inline bool MultiSolvers::addClause (const vec& ps) { ps.copyTo(add_tmp); return addClause_(add_tmp); } inline void MultiSolvers::setVerbosity(int i) {verb = i;} inline void MultiSolvers::setVerbEveryConflicts(int i) {verbEveryConflicts=i;} inline int MultiSolvers::nVars () const { return numvar; } inline int MultiSolvers::nClauses () const { return numclauses; } inline int MultiSolvers::verbosity() {return verb;} inline ParallelSolver* MultiSolvers::getPrimarySolver() {return solvers[0];} } #endif