/// Post constraint on \a x virtual void post(Space& home, SetVarArray& x, IntVarArray&) { SetVarArgs xs(x.size()-2); for (int i=x.size()-2; i--;) xs[i]=x[i]; Gecode::element(home, SOT_INTER, xs, x[x.size()-2], x[x.size()-1], ds_12); }
/// Actual model Golf(const GolfOptions& opt) : g(opt.g()), s(opt.s()), w(opt.w()), groups(*this,g*w,IntSet::empty,0,g*s-1,s,s) { Matrix<SetVarArray> schedule(groups,g,w); // Groups in one week must be disjoint SetVar allPlayers(*this, 0,g*s-1, 0,g*s-1); for (int i=0; i<w; i++) rel(*this, setdunion(schedule.row(i)) == allPlayers); // No two golfers play in the same group more than once for (int i=0; i<groups.size()-1; i++) for (int j=i+1; j<groups.size(); j++) rel(*this, cardinality(groups[i] & groups[j]) <= 1); if (opt.model() == MODEL_SYMMETRY) { /* * Redundant constraints and static symmetry breaking from * "Solving Kirkman's Schoolgirl Problem in a Few Seconds" * Nicolas Barnier, Pascal Brisset, Constraints, 10, 7-21, 2005 * */ // Redundant constraint: // in each week, one player plays in only one group for (int j=0; j<w; j++) { for (int p=0; p < g*s; p++) { BoolVarArgs b(g); for (int i=0; i<g; i++) b[i] = expr(*this, (singleton(p) <= schedule(i,j))); linear(*this, b, IRT_EQ, 1); } } // Symmetry breaking: order groups for (int j=0; j<w; j++) { IntVarArgs m(g); for (int i=0; i<g; i++) m[i] = expr(*this, min(schedule(i,j))); rel(*this, m, IRT_LE); } // Symmetry breaking: order weeks // minElem(group(w,0)\{0}) < minElem(group(w+1,0)\{0}) { IntVarArgs m(w); for (int i=0; i<w; i++) m[i] = expr(*this, min(schedule(0,i)-IntSet(0,0))); rel(*this, m, IRT_LE); } // Symmetry breaking: value symmetry of player numbers precede(*this, groups, IntArgs::create(groups.size(),0)); } branch(*this, groups, SET_VAR_MIN_MIN, SET_VAL_MIN_INC); }
/// Actual model Hamming(const HammingOptions& opt) : x(*this,opt.size(),IntSet::empty,1,opt.bits()) { SetVarArgs cx(x.size()); for (int i=x.size(); i--;) cx[i] = expr(*this, -x[i]); for (int i=0; i<x.size(); i++) for (int j=i+1; j<x.size(); j++) rel(*this, cardinality(x[j] & cx[i]) + cardinality(x[i] & cx[j]) >= opt.distance()); branch(*this, x, SET_VAR_NONE, SET_VAL_MIN_INC); }
/// Print solution virtual void print(std::ostream& os) const { for (int i=0; i<xs.size(); i++) { os << "\t[" << i << "] = " << xs[i] << std::endl; } print_to_string(); }
virtual void print_to_string() const { std::ostringstream outputstring; outputstring << "(" ; for (int i=0; i<xs.size(); i++) { outputstring << "(" ; for (int j=0;j<=xs[i].glbMax();j++) if (xs[i].contains(j)) outputstring << j << " " ; outputstring << ")" ; } outputstring << ")" ; std::cout << "OUTPUT" << outputstring.str(); strcpy(result,outputstring.str().c_str()); }
/// Post constraint on \a x virtual void post(Space& home, SetVarArray& x, IntVarArray&) { SetVarArgs xs(x.size()-1); for (int i=x.size()-1; i--;) xs[i]=x[i]; Gecode::sequence(home, xs, x[x.size()-1]); }
//int bpfs[1][12]; /// Actual model Profils(const ProfilsOptions& opt) : Script(opt), xs(*this,opt.size(),IntSet::empty,1,opt.nn()) { # if 0 // was the hamming constrain SetVarArray cxs(*this,xs.size()); for (int i=0; i<xs.size(); i++) rel(*this, xs[i], SRT_CMPL, cxs[i]); for (int i=0; i<xs.size(); i++) { SetVar y = xs[i]; SetVar cy = cxs[i]; for (int j=i+1; j<xs.size(); j++) { SetVar x = xs[j]; SetVar cx = cxs[j]; SetVar xIntCy(*this); SetVar yIntCx(*this); rel(*this, x, SOT_INTER, cy, SRT_EQ, xIntCy); rel(*this, y, SOT_INTER, cx, SRT_EQ, yIntCx); IntVar xIntCyCard(*this,0,x.cardMax()); IntVar yIntCxCard(*this,0,y.cardMax()); cardinality(*this, xIntCy, xIntCyCard); cardinality(*this, yIntCx, yIntCxCard); post(*this, xIntCyCard+yIntCxCard >= opt.distance()); } } #endif for (int i=0; i<(xs.size() - 1); i++) { IntVar min0(*this,0,120); IntVar min1(*this,0,120); IntVar max0(*this,0,120); IntVar max1(*this,0,120); min(*this,xs[i],min0); min(*this,xs[i+1],min1); if (opt.profils[0][i] == 1) rel(*this, min1,IRT_GR, min0); else rel(*this, min1,IRT_LE, min0); max(*this,xs[i],max0); max(*this,xs[i+1],max1); if (opt.profils[1][i] == 1) rel(*this, max1,IRT_GR, max0); else rel(*this, max1,IRT_LE, max0); } //contrainte de cardinalité IntVar card(*this,opt.densMin,opt.densMax); for (int i=0; i<(xs.size()); i++) cardinality(*this, xs[i], card); branch(*this, xs, SET_VAR_NONE(), SET_VAL_MIN_INC()); }
/// Print solution virtual void print(std::ostream& os) const { for (int i=0; i<x.size(); i++) { os << "\t[" << i << "] = " << x[i] << std::endl; } }
/// Post constraint on \a x virtual void post(Space& home, SetVarArray& x, IntVarArray& y) { SetVarArgs xs(x.size()-1); for (int i=x.size()-1; i--;) xs[i]=x[i]; Gecode::element(home, xs, y[0], x[x.size()-1]); }