bool Transformer::allConsAssigned_(ProblemPtr p, HandlerVector &handlers) { BoolVector asgn(p->getNumCons(), false); for (HandlerVector::const_iterator it=handlers.begin(); it!=handlers.end(); ++it) { for (ConstraintVector::const_iterator it2=(*it)->consBegin(); it2!=(*it)->consEnd(); ++it2) { if (asgn[(*it2)->getIndex()] == true) { std::cout << "constraint " << (*it2)->getName() << " with index " << (*it2)->getIndex() << " is assigned to more than one handlers!" << std::endl; (*it2)->write(std::cout); return false; } asgn[(*it2)->getIndex()] = true; } } for (UInt it=0; it<p->getNumCons(); ++it) { if (asgn[it] != true) { std::cout << "constraint " << p->getConstraint(it)->getName() << " with index " << it << " is not assigned to any handler!" << std::endl; p->getConstraint(it)->write(std::cout); return false; } } return true; }
void Transformer::clearUnusedHandlers_(HandlerVector &handlers) { for (HandlerVector::iterator it=handlers.begin(); it!=handlers.end();) { if (false == (*it)->isNeeded()) { it = handlers.erase(it); } else { ++it; } } }
PresolverPtr presolve(EnvPtr env, ProblemPtr p, size_t ndefs, HandlerVector &handlers) { PresolverPtr pres = PresolverPtr(); // NULL const std::string me("qg: "); p->calculateSize(); if (env->getOptions()->findBool("presolve")->getValue() == true) { LinearHandlerPtr lhandler = (LinearHandlerPtr) new LinearHandler(env, p); handlers.push_back(lhandler); if (p->isQP() || p->isQuadratic() || p->isLinear() || true==env->getOptions()->findBool("use_native_cgraph")->getValue()) { lhandler->setPreOptPurgeVars(true); lhandler->setPreOptPurgeCons(true); lhandler->setPreOptCoeffImp(true); } else { lhandler->setPreOptPurgeVars(false); lhandler->setPreOptPurgeCons(false); lhandler->setPreOptCoeffImp(false); } if (ndefs>0) { lhandler->setPreOptDualFix(false); } else { lhandler->setPreOptDualFix(true); } if (!p->isLinear() && true==env->getOptions()->findBool("use_native_cgraph")->getValue() && true==env->getOptions()->findBool("nl_presolve")->getValue() ) { NlPresHandlerPtr nlhand = (NlPresHandlerPtr) new NlPresHandler(env, p); handlers.push_back(nlhand); } // write the names. env->getLogger()->msgStream(LogExtraInfo) << me << "handlers used in presolve:" << std::endl; for (HandlerIterator h = handlers.begin(); h != handlers.end(); ++h) { env->getLogger()->msgStream(LogExtraInfo) << me << (*h)->getName() << std::endl; } } pres = (PresolverPtr) new Presolver(p, env, handlers); pres->standardize(); if (env->getOptions()->findBool("presolve")->getValue() == true) { pres->solve(); } return pres; }
void AMPLOsiUT::testOsiBnB() { EnvPtr env = (EnvPtr) new Environment(); char file_name[] = "instances/milp"; HandlerVector handlers; ReliabilityBrancherPtr br; EnginePtr e; int err = 0; env->startTimer(err); ProblemPtr p = iface_->readInstance(file_name); BranchAndBound *bab = new BranchAndBound(env, p); IntVarHandlerPtr v_hand = (IntVarHandlerPtr) new IntVarHandler(env, p); LinearHandlerPtr l_hand = (LinearHandlerPtr) new LinearHandler(env, p); handlers.push_back(v_hand); handlers.push_back(l_hand); v_hand->setModFlags(false, true); l_hand->setModFlags(false, true); EngineFactory efac(env); e = efac.getLPEngine(); PCBProcessorPtr nproc = (PCBProcessorPtr) new PCBProcessor(env, e, handlers); br= (ReliabilityBrancherPtr) new ReliabilityBrancher(env, handlers); br->setEngine(e); nproc->setBrancher(br); bab->setNodeProcessor(nproc); NodeIncRelaxerPtr nr = (NodeIncRelaxerPtr) new NodeIncRelaxer(env, handlers); bab->setNodeRelaxer(nr); nr->setEngine(e); nr->setModFlag(false); p->setNativeDer(); bab->shouldCreateRoot(true); bab->setLogLevel(LogNone); bab->solve(); CPPUNIT_ASSERT(bab->getUb() == 1.0); delete bab; }
int main(int argc, char* argv[]) { EnvPtr env = (EnvPtr) new Environment(); OptionDBPtr options; MINOTAUR_AMPL::AMPLInterfacePtr iface = MINOTAUR_AMPL::AMPLInterfacePtr(); ProblemPtr inst; SolutionPtr sol, sol2; double obj_sense =1.0; // jacobian is read from AMPL interface and passed on to branch-and-bound JacobianPtr jPtr; // hessian is read from AMPL interface and passed on to branch-and-bound MINOTAUR_AMPL::AMPLHessianPtr hPtr; // the branch-and-bound BranchAndBound *bab = 0; PresolverPtr pres; EngineFactory *efac; const std::string me("qg: "); BrancherPtr br = BrancherPtr(); // NULL PCBProcessorPtr nproc; NodeIncRelaxerPtr nr; //handlers HandlerVector handlers; IntVarHandlerPtr vHand; LinearHandlerPtr lHand; QGAdvHandlerPtr qgHand; RCHandlerPtr rcHand; //engines EnginePtr nlp_e; EnginePtr proj_nlp_e; EnginePtr l1proj_nlp_e; LPEnginePtr lin_e; // lp engine LoggerPtr logger_ = (LoggerPtr) new Logger(LogInfo); VarVector *orig_v=0; int err = 0; // start timing. env->startTimer(err); if (err) { goto CLEANUP; } setInitialOptions(env); iface = (MINOTAUR_AMPL::AMPLInterfacePtr) new MINOTAUR_AMPL::AMPLInterface(env, "qg"); // parse options env->readOptions(argc, argv); options = env->getOptions(); options->findString("interface_type")->setValue("AMPL"); if (0!=showInfo(env)) { goto CLEANUP; } loadProblem(env, iface, inst, &obj_sense); // Initialize engines nlp_e = getNLPEngine(env, inst); //Engine for Original problem efac = new EngineFactory(env); lin_e = efac->getLPEngine(); // lp engine delete efac; // get presolver. orig_v = new VarVector(inst->varsBegin(), inst->varsEnd()); pres = presolve(env, inst, iface->getNumDefs(), handlers); handlers.clear(); if (Finished != pres->getStatus() && NotStarted != pres->getStatus()) { env->getLogger()->msgStream(LogInfo) << me << "status of presolve: " << getSolveStatusString(pres->getStatus()) << std::endl; writeSol(env, orig_v, pres, SolutionPtr(), pres->getStatus(), iface); writeBnbStatus(env, bab, obj_sense); goto CLEANUP; } if (options->findBool("solve")->getValue()==true) { if (true==options->findBool("use_native_cgraph")->getValue()) { inst->setNativeDer(); } // Initialize the handlers for branch-and-cut lHand = (LinearHandlerPtr) new LinearHandler(env, inst); lHand->setModFlags(false, true); handlers.push_back(lHand); assert(lHand); vHand = (IntVarHandlerPtr) new IntVarHandler(env, inst); vHand->setModFlags(false, true); handlers.push_back(vHand); assert(vHand); // Use of perspective handler is user choice if (env->getOptions()->findBool("perspective")->getValue() == true) { PerspCutHandlerPtr pcHand = (PerspCutHandlerPtr) new PerspCutHandler(env, inst); pcHand->findPRCons(); if (pcHand->getStatus()) { qgHand = (QGAdvHandlerPtr) new QGAdvHandler(env, inst, nlp_e, pcHand); } else { qgHand = (QGAdvHandlerPtr) new QGAdvHandler(env, inst, nlp_e); } } else { qgHand = (QGAdvHandlerPtr) new QGAdvHandler(env, inst, nlp_e); } qgHand->setModFlags(false, true); handlers.push_back(qgHand); assert(qgHand); if (options->findBool("rc_fix")->getValue()) { rcHand = (RCHandlerPtr) new RCHandler(env); rcHand->setModFlags(false, true); handlers.push_back(rcHand); assert(rcHand); } // report name env->getLogger()->msgStream(LogExtraInfo) << me << "handlers used:" << std::endl; for (HandlerIterator h = handlers.begin(); h != handlers.end(); ++h) { env->getLogger()->msgStream(LogExtraInfo) << me << (*h)->getName() << std::endl; } // Only store bound-changes of relaxation (not problem) nr = (NodeIncRelaxerPtr) new NodeIncRelaxer(env, handlers); nr->setModFlag(false); nr->setEngine(lin_e); nproc = (PCBProcessorPtr) new PCBProcessor(env, lin_e, handlers); if (env->getOptions()->findString("brancher")->getValue() == "rel") { ReliabilityBrancherPtr rel_br = (ReliabilityBrancherPtr) new ReliabilityBrancher(env, handlers); rel_br->setEngine(lin_e); nproc->setBrancher(rel_br); br = rel_br; } else if (env->getOptions()->findString("brancher")->getValue() == "maxvio") { MaxVioBrancherPtr mbr = (MaxVioBrancherPtr) new MaxVioBrancher(env, handlers); nproc->setBrancher(mbr); br = mbr; } else if (env->getOptions()->findString("brancher")->getValue() == "lex") { LexicoBrancherPtr lbr = (LexicoBrancherPtr) new LexicoBrancher(env, handlers); br = lbr; } nproc->setBrancher(br); env->getLogger()->msgStream(LogExtraInfo) << me << "brancher used = " << br->getName() << std::endl; bab = new BranchAndBound(env, inst); bab->setNodeRelaxer(nr); bab->setNodeProcessor(nproc); bab->shouldCreateRoot(true); // start solving bab->solve(); bab->writeStats(env->getLogger()->msgStream(LogExtraInfo)); //bab->writeStats(std::cout); nlp_e->writeStats(env->getLogger()->msgStream(LogExtraInfo)); lin_e->writeStats(env->getLogger()->msgStream(LogExtraInfo)); for (HandlerVector::iterator it=handlers.begin(); it!=handlers.end(); ++it) { //(*it)->writeStats(std::cout); (*it)->writeStats(env->getLogger()->msgStream(LogExtraInfo)); } writeSol(env, orig_v, pres, bab->getSolution(), bab->getStatus(), iface); writeBnbStatus(env, bab, obj_sense); } CLEANUP: if (iface) { delete iface; } if (orig_v) { delete orig_v; } if (bab) { delete bab; } return 0; }