/** LP solution separation method of separator */ static SCIP_DECL_SEPAEXECLP(sepaExeclpGomory) { /*lint --e{715}*/ SCIP_SEPADATA* sepadata; SCIP_VAR** vars; SCIP_COL** cols; SCIP_ROW** rows; SCIP_Real* binvrow; SCIP_Real* cutcoefs; SCIP_Real maxscale; SCIP_Real minfrac; SCIP_Real maxfrac; SCIP_Longint maxdnom; SCIP_Bool cutoff; int* basisind; int naddedcuts; int nvars; int ncols; int nrows; int ncalls; int depth; int maxdepth; int maxsepacuts; int c; int i; assert(sepa != NULL); assert(strcmp(SCIPsepaGetName(sepa), SEPA_NAME) == 0); assert(scip != NULL); assert(result != NULL); *result = SCIP_DIDNOTRUN; sepadata = SCIPsepaGetData(sepa); assert(sepadata != NULL); depth = SCIPgetDepth(scip); ncalls = SCIPsepaGetNCallsAtNode(sepa); minfrac = sepadata->away; maxfrac = 1.0 - sepadata->away; /* only call separator, if we are not close to terminating */ if( SCIPisStopped(scip) ) return SCIP_OKAY; /* only call the gomory cut separator a given number of times at each node */ if( (depth == 0 && sepadata->maxroundsroot >= 0 && ncalls >= sepadata->maxroundsroot) || (depth > 0 && sepadata->maxrounds >= 0 && ncalls >= sepadata->maxrounds) ) return SCIP_OKAY; /* only call separator, if an optimal LP solution is at hand */ if( SCIPgetLPSolstat(scip) != SCIP_LPSOLSTAT_OPTIMAL ) return SCIP_OKAY; /* only call separator, if the LP solution is basic */ if( !SCIPisLPSolBasic(scip) ) return SCIP_OKAY; /* only call separator, if there are fractional variables */ if( SCIPgetNLPBranchCands(scip) == 0 ) return SCIP_OKAY; /* get variables data */ SCIP_CALL( SCIPgetVarsData(scip, &vars, &nvars, NULL, NULL, NULL, NULL) ); /* get LP data */ SCIP_CALL( SCIPgetLPColsData(scip, &cols, &ncols) ); SCIP_CALL( SCIPgetLPRowsData(scip, &rows, &nrows) ); if( ncols == 0 || nrows == 0 ) return SCIP_OKAY; #if 0 /* if too many columns, separator is usually very slow: delay it until no other cuts have been found */ if( ncols >= 50*nrows ) return SCIP_OKAY; if( ncols >= 5*nrows ) { int ncutsfound; ncutsfound = SCIPgetNCutsFound(scip); if( ncutsfound > sepadata->lastncutsfound || !SCIPsepaWasLPDelayed(sepa) ) { sepadata->lastncutsfound = ncutsfound; *result = SCIP_DELAYED; return SCIP_OKAY; } } #endif /* set the maximal denominator in rational representation of gomory cut and the maximal scale factor to * scale resulting cut to integral values to avoid numerical instabilities */ /**@todo find better but still stable gomory cut settings: look at dcmulti, gesa3, khb0525, misc06, p2756 */ maxdepth = SCIPgetMaxDepth(scip); if( depth == 0 ) { maxdnom = 1000; maxscale = 1000.0; } else if( depth <= maxdepth/4 ) { maxdnom = 1000; maxscale = 1000.0; } else if( depth <= maxdepth/2 ) { maxdnom = 100; maxscale = 100.0; } else { maxdnom = 10; maxscale = 10.0; } /* allocate temporary memory */ SCIP_CALL( SCIPallocBufferArray(scip, &cutcoefs, nvars) ); SCIP_CALL( SCIPallocBufferArray(scip, &basisind, nrows) ); SCIP_CALL( SCIPallocBufferArray(scip, &binvrow, nrows) ); /* get basis indices */ SCIP_CALL( SCIPgetLPBasisInd(scip, basisind) ); /* get the maximal number of cuts allowed in a separation round */ if( depth == 0 ) maxsepacuts = sepadata->maxsepacutsroot; else maxsepacuts = sepadata->maxsepacuts; SCIPdebugMessage("searching gomory cuts: %d cols, %d rows, maxdnom=%"SCIP_LONGINT_FORMAT", maxscale=%g, maxcuts=%d\n", ncols, nrows, maxdnom, maxscale, maxsepacuts); cutoff = FALSE; naddedcuts = 0; /* for all basic columns belonging to integer variables, try to generate a gomory cut */ for( i = 0; i < nrows && naddedcuts < maxsepacuts && !SCIPisStopped(scip) && !cutoff; ++i ) { SCIP_Bool tryrow; tryrow = FALSE; c = basisind[i]; if( c >= 0 ) { SCIP_VAR* var; assert(c < ncols); var = SCIPcolGetVar(cols[c]); if( SCIPvarGetType(var) != SCIP_VARTYPE_CONTINUOUS ) { SCIP_Real primsol; primsol = SCIPcolGetPrimsol(cols[c]); assert(SCIPgetVarSol(scip, var) == primsol); /*lint !e777*/ if( SCIPfeasFrac(scip, primsol) >= minfrac ) { SCIPdebugMessage("trying gomory cut for col <%s> [%g]\n", SCIPvarGetName(var), primsol); tryrow = TRUE; } } } else if( sepadata->separaterows ) { SCIP_ROW* row; assert(0 <= -c-1 && -c-1 < nrows); row = rows[-c-1]; if( SCIProwIsIntegral(row) && !SCIProwIsModifiable(row) ) { SCIP_Real primsol; primsol = SCIPgetRowActivity(scip, row); if( SCIPfeasFrac(scip, primsol) >= minfrac ) { SCIPdebugMessage("trying gomory cut for row <%s> [%g]\n", SCIProwGetName(row), primsol); tryrow = TRUE; } } } if( tryrow ) { SCIP_Real cutrhs; SCIP_Real cutact; SCIP_Bool success; SCIP_Bool cutislocal; /* get the row of B^-1 for this basic integer variable with fractional solution value */ SCIP_CALL( SCIPgetLPBInvRow(scip, i, binvrow) ); cutact = 0.0; cutrhs = SCIPinfinity(scip); /* create a MIR cut out of the weighted LP rows using the B^-1 row as weights */ SCIP_CALL( SCIPcalcMIR(scip, NULL, BOUNDSWITCH, USEVBDS, ALLOWLOCAL, FIXINTEGRALRHS, NULL, NULL, (int) MAXAGGRLEN(nvars), sepadata->maxweightrange, minfrac, maxfrac, binvrow, 1.0, NULL, NULL, cutcoefs, &cutrhs, &cutact, &success, &cutislocal) ); assert(ALLOWLOCAL || !cutislocal); /* @todo Currently we are using the SCIPcalcMIR() function to compute the coefficients of the Gomory * cut. Alternatively, we could use the direct version (see thesis of Achterberg formula (8.4)) which * leads to cut a of the form \sum a_i x_i \geq 1. Rumor has it that these cuts are better. */ SCIPdebugMessage(" -> success=%u: %g <= %g\n", success, cutact, cutrhs); /* if successful, convert dense cut into sparse row, and add the row as a cut */ if( success && SCIPisFeasGT(scip, cutact, cutrhs) ) { SCIP_ROW* cut; char cutname[SCIP_MAXSTRLEN]; int v; /* construct cut name */ if( c >= 0 ) (void) SCIPsnprintf(cutname, SCIP_MAXSTRLEN, "gom%d_x%d", SCIPgetNLPs(scip), c); else (void) SCIPsnprintf(cutname, SCIP_MAXSTRLEN, "gom%d_s%d", SCIPgetNLPs(scip), -c-1); /* create empty cut */ SCIP_CALL( SCIPcreateEmptyRowSepa(scip, &cut, sepa, cutname, -SCIPinfinity(scip), cutrhs, cutislocal, FALSE, sepadata->dynamiccuts) ); /* cache the row extension and only flush them if the cut gets added */ SCIP_CALL( SCIPcacheRowExtensions(scip, cut) ); /* collect all non-zero coefficients */ for( v = 0; v < nvars; ++v ) { if( !SCIPisZero(scip, cutcoefs[v]) ) { SCIP_CALL( SCIPaddVarToRow(scip, cut, vars[v], cutcoefs[v]) ); } } if( SCIProwGetNNonz(cut) == 0 ) { assert(SCIPisFeasNegative(scip, cutrhs)); SCIPdebugMessage(" -> gomory cut detected infeasibility with cut 0 <= %f\n", cutrhs); cutoff = TRUE; } else if( SCIProwGetNNonz(cut) == 1 ) { /* add the bound change as cut to avoid that the LP gets modified. that would mean the LP is not flushed * and the method SCIPgetLPBInvRow() fails; SCIP internally will apply that bound change automatically */ SCIP_CALL( SCIPaddCut(scip, NULL, cut, TRUE) ); naddedcuts++; } else { /* Only take efficacious cuts, except for cuts with one non-zero coefficients (= bound * changes); the latter cuts will be handeled internally in sepastore. */ if( SCIPisCutEfficacious(scip, NULL, cut) ) { assert(success == TRUE); SCIPdebugMessage(" -> gomory cut for <%s>: act=%f, rhs=%f, eff=%f\n", c >= 0 ? SCIPvarGetName(SCIPcolGetVar(cols[c])) : SCIProwGetName(rows[-c-1]), cutact, cutrhs, SCIPgetCutEfficacy(scip, NULL, cut)); if( sepadata->makeintegral ) { /* try to scale the cut to integral values */ SCIP_CALL( SCIPmakeRowIntegral(scip, cut, -SCIPepsilon(scip), SCIPsumepsilon(scip), maxdnom, maxscale, MAKECONTINTEGRAL, &success) ); if( sepadata->forcecuts ) success = TRUE; /* in case the left hand side in minus infinity and the right hand side is plus infinity the cut is * useless so we are not taking it at all */ if( (SCIPisInfinity(scip, -SCIProwGetLhs(cut)) && SCIPisInfinity(scip, SCIProwGetRhs(cut))) ) success = FALSE; /* @todo Trying to make the Gomory cut integral might fail. Due to numerical reasons/arguments we * currently ignore such cuts. If the cut, however, has small support (let's say smaller or equal to * 5), we might want to add that cut (even it does not have integral coefficients). To be able to * do that we need to add a rank to the data structure of a row. The rank of original rows are * zero and for aggregated rows it is the maximum over all used rows plus one. */ } if( success ) { SCIPdebugMessage(" -> found gomory cut <%s>: act=%f, rhs=%f, norm=%f, eff=%f, min=%f, max=%f (range=%f)\n", cutname, SCIPgetRowLPActivity(scip, cut), SCIProwGetRhs(cut), SCIProwGetNorm(cut), SCIPgetCutEfficacy(scip, NULL, cut), SCIPgetRowMinCoef(scip, cut), SCIPgetRowMaxCoef(scip, cut), SCIPgetRowMaxCoef(scip, cut)/SCIPgetRowMinCoef(scip, cut)); /* flush all changes before adding the cut */ SCIP_CALL( SCIPflushRowExtensions(scip, cut) ); /* add global cuts which are not implicit bound changes to the cut pool */ if( !cutislocal ) { if( sepadata->delayedcuts ) { SCIP_CALL( SCIPaddDelayedPoolCut(scip, cut) ); } else { SCIP_CALL( SCIPaddPoolCut(scip, cut) ); } } else { /* local cuts we add to the sepastore */ SCIP_CALL( SCIPaddCut(scip, NULL, cut, FALSE) ); } naddedcuts++; } } } /* release the row */ SCIP_CALL( SCIPreleaseRow(scip, &cut) ); } } } /* free temporary memory */ SCIPfreeBufferArray(scip, &binvrow); SCIPfreeBufferArray(scip, &basisind); SCIPfreeBufferArray(scip, &cutcoefs); SCIPdebugMessage("end searching gomory cuts: found %d cuts\n", naddedcuts); sepadata->lastncutsfound = SCIPgetNCutsFound(scip); /* evalute the result of the separation */ if( cutoff ) *result = SCIP_CUTOFF; else if ( naddedcuts > 0 ) *result = SCIP_SEPARATED; else *result = SCIP_DIDNOTFIND; return SCIP_OKAY; }
/** LP solution separation method of separator */ static SCIP_DECL_SEPAEXECLP(sepaExeclpStrongcg) { /*lint --e{715}*/ SCIP_SEPADATA* sepadata; SCIP_VAR** vars; SCIP_COL** cols; SCIP_ROW** rows; SCIP_Real* varsolvals; SCIP_Real* binvrow; SCIP_Real* cutcoefs; SCIP_Real cutrhs; SCIP_Real cutact; SCIP_Real maxscale; SCIP_Longint maxdnom; int* basisind; int* inds; int ninds; int nvars; int ncols; int nrows; int ncalls; int depth; int maxdepth; int maxsepacuts; int ncuts; int c; int i; int cutrank; SCIP_Bool success; SCIP_Bool cutislocal; char normtype; assert(sepa != NULL); assert(strcmp(SCIPsepaGetName(sepa), SEPA_NAME) == 0); assert(scip != NULL); assert(result != NULL); *result = SCIP_DIDNOTRUN; sepadata = SCIPsepaGetData(sepa); assert(sepadata != NULL); depth = SCIPgetDepth(scip); ncalls = SCIPsepaGetNCallsAtNode(sepa); /* only call separator, if we are not close to terminating */ if( SCIPisStopped(scip) ) return SCIP_OKAY; /* only call the strong CG cut separator a given number of times at each node */ if( (depth == 0 && sepadata->maxroundsroot >= 0 && ncalls >= sepadata->maxroundsroot) || (depth > 0 && sepadata->maxrounds >= 0 && ncalls >= sepadata->maxrounds) ) return SCIP_OKAY; /* only call separator, if an optimal LP solution is at hand */ if( SCIPgetLPSolstat(scip) != SCIP_LPSOLSTAT_OPTIMAL ) return SCIP_OKAY; /* only call separator, if the LP solution is basic */ if( !SCIPisLPSolBasic(scip) ) return SCIP_OKAY; /* only call separator, if there are fractional variables */ if( SCIPgetNLPBranchCands(scip) == 0 ) return SCIP_OKAY; /* get variables data */ SCIP_CALL( SCIPgetVarsData(scip, &vars, &nvars, NULL, NULL, NULL, NULL) ); /* get LP data */ SCIP_CALL( SCIPgetLPColsData(scip, &cols, &ncols) ); SCIP_CALL( SCIPgetLPRowsData(scip, &rows, &nrows) ); if( ncols == 0 || nrows == 0 ) return SCIP_OKAY; #if 0 /* if too many columns, separator is usually very slow: delay it until no other cuts have been found */ if( ncols >= 50*nrows ) return SCIP_OKAY; if( ncols >= 5*nrows ) { int ncutsfound; ncutsfound = SCIPgetNCutsFound(scip); if( ncutsfound > sepadata->lastncutsfound || !SCIPsepaWasLPDelayed(sepa) ) { sepadata->lastncutsfound = ncutsfound; *result = SCIP_DELAYED; return SCIP_OKAY; } } #endif /* get the type of norm to use for efficacy calculations */ SCIP_CALL( SCIPgetCharParam(scip, "separating/efficacynorm", &normtype) ); /* set the maximal denominator in rational representation of strong CG cut and the maximal scale factor to * scale resulting cut to integral values to avoid numerical instabilities */ /**@todo find better but still stable strong CG cut settings: look at dcmulti, gesa3, khb0525, misc06, p2756 */ maxdepth = SCIPgetMaxDepth(scip); if( depth == 0 ) { maxdnom = 1000; maxscale = 1000.0; } else if( depth <= maxdepth/4 ) { maxdnom = 1000; maxscale = 1000.0; } else if( depth <= maxdepth/2 ) { maxdnom = 100; maxscale = 100.0; } else { maxdnom = 10; maxscale = 10.0; } *result = SCIP_DIDNOTFIND; /* allocate temporary memory */ SCIP_CALL( SCIPallocBufferArray(scip, &cutcoefs, nvars) ); SCIP_CALL( SCIPallocBufferArray(scip, &basisind, nrows) ); SCIP_CALL( SCIPallocBufferArray(scip, &binvrow, nrows) ); SCIP_CALL( SCIPallocBufferArray(scip, &inds, nrows) ); varsolvals = NULL; /* allocate this later, if needed */ /* get basis indices */ SCIP_CALL( SCIPgetLPBasisInd(scip, basisind) ); /* get the maximal number of cuts allowed in a separation round */ if( depth == 0 ) maxsepacuts = sepadata->maxsepacutsroot; else maxsepacuts = sepadata->maxsepacuts; SCIPdebugMessage("searching strong CG cuts: %d cols, %d rows, maxdnom=%" SCIP_LONGINT_FORMAT ", maxscale=%g, maxcuts=%d\n", ncols, nrows, maxdnom, maxscale, maxsepacuts); /* for all basic columns belonging to integer variables, try to generate a strong CG cut */ ncuts = 0; for( i = 0; i < nrows && ncuts < maxsepacuts && !SCIPisStopped(scip) && *result != SCIP_CUTOFF; ++i ) { SCIP_Bool tryrow; tryrow = FALSE; c = basisind[i]; if( c >= 0 ) { SCIP_VAR* var; assert(c < ncols); var = SCIPcolGetVar(cols[c]); if( SCIPvarGetType(var) != SCIP_VARTYPE_CONTINUOUS ) { SCIP_Real primsol; primsol = SCIPcolGetPrimsol(cols[c]); assert(SCIPgetVarSol(scip, var) == primsol); /*lint !e777*/ if( SCIPfeasFrac(scip, primsol) >= MINFRAC ) { SCIPdebugMessage("trying strong CG cut for col <%s> [%g]\n", SCIPvarGetName(var), primsol); tryrow = TRUE; } } } #ifdef SEPARATEROWS else { SCIP_ROW* row; assert(0 <= -c-1 && -c-1 < nrows); row = rows[-c-1]; if( SCIProwIsIntegral(row) && !SCIProwIsModifiable(row) ) { SCIP_Real primsol; primsol = SCIPgetRowActivity(scip, row); if( SCIPfeasFrac(scip, primsol) >= MINFRAC ) { SCIPdebugMessage("trying strong CG cut for row <%s> [%g]\n", SCIProwGetName(row), primsol); tryrow = TRUE; } } } #endif if( tryrow ) { /* get the row of B^-1 for this basic integer variable with fractional solution value */ SCIP_CALL( SCIPgetLPBInvRow(scip, i, binvrow, inds, &ninds) ); #ifdef SCIP_DEBUG /* initialize variables, that might not have been initialized in SCIPcalcMIR if success == FALSE */ cutact = 0.0; cutrhs = SCIPinfinity(scip); #endif /* create a strong CG cut out of the weighted LP rows using the B^-1 row as weights */ SCIP_CALL( SCIPcalcStrongCG(scip, BOUNDSWITCH, USEVBDS, ALLOWLOCAL, (int) MAXAGGRLEN(nvars), sepadata->maxweightrange, MINFRAC, MAXFRAC, binvrow, inds, ninds, 1.0, cutcoefs, &cutrhs, &cutact, &success, &cutislocal, &cutrank) ); assert(ALLOWLOCAL || !cutislocal); SCIPdebugMessage(" -> success=%u: %g <= %g\n", success, cutact, cutrhs); /* if successful, convert dense cut into sparse row, and add the row as a cut */ if( success && SCIPisFeasGT(scip, cutact, cutrhs) ) { SCIP_VAR** cutvars; SCIP_Real* cutvals; SCIP_Real cutnorm; int cutlen; /* if this is the first successful cut, get the LP solution for all COLUMN variables */ if( varsolvals == NULL ) { int v; SCIP_CALL( SCIPallocBufferArray(scip, &varsolvals, nvars) ); for( v = 0; v < nvars; ++v ) { if( SCIPvarGetStatus(vars[v]) == SCIP_VARSTATUS_COLUMN ) varsolvals[v] = SCIPvarGetLPSol(vars[v]); } } assert(varsolvals != NULL); /* get temporary memory for storing the cut as sparse row */ SCIP_CALL( SCIPallocBufferArray(scip, &cutvars, nvars) ); SCIP_CALL( SCIPallocBufferArray(scip, &cutvals, nvars) ); /* store the cut as sparse row, calculate activity and norm of cut */ SCIP_CALL( storeCutInArrays(scip, nvars, vars, cutcoefs, varsolvals, normtype, cutvars, cutvals, &cutlen, &cutact, &cutnorm) ); SCIPdebugMessage(" -> strong CG cut for <%s>: act=%f, rhs=%f, norm=%f, eff=%f, rank=%d\n", c >= 0 ? SCIPvarGetName(SCIPcolGetVar(cols[c])) : SCIProwGetName(rows[-c-1]), cutact, cutrhs, cutnorm, (cutact - cutrhs)/cutnorm, cutrank); if( SCIPisPositive(scip, cutnorm) && SCIPisEfficacious(scip, (cutact - cutrhs)/cutnorm) ) { SCIP_ROW* cut; char cutname[SCIP_MAXSTRLEN]; /* create the cut */ if( c >= 0 ) (void) SCIPsnprintf(cutname, SCIP_MAXSTRLEN, "scg%d_x%d", SCIPgetNLPs(scip), c); else (void) SCIPsnprintf(cutname, SCIP_MAXSTRLEN, "scg%d_s%d", SCIPgetNLPs(scip), -c-1); SCIP_CALL( SCIPcreateEmptyRowSepa(scip, &cut, sepa, cutname, -SCIPinfinity(scip), cutrhs, cutislocal, FALSE, sepadata->dynamiccuts) ); SCIP_CALL( SCIPaddVarsToRow(scip, cut, cutlen, cutvars, cutvals) ); /*SCIPdebug( SCIP_CALL(SCIPprintRow(scip, cut, NULL)) );*/ SCIProwChgRank(cut, cutrank); assert(success); #ifdef MAKECUTINTEGRAL /* try to scale the cut to integral values */ SCIP_CALL( SCIPmakeRowIntegral(scip, cut, -SCIPepsilon(scip), SCIPsumepsilon(scip), maxdnom, maxscale, MAKECONTINTEGRAL, &success) ); #else #ifdef MAKEINTCUTINTEGRAL /* try to scale the cut to integral values if there are no continuous variables * -> leads to an integral slack variable that can later be used for other cuts */ { int k = 0; while ( k < cutlen && SCIPvarIsIntegral(cutvars[k]) ) ++k; if( k == cutlen ) { SCIP_CALL( SCIPmakeRowIntegral(scip, cut, -SCIPepsilon(scip), SCIPsumepsilon(scip), maxdnom, maxscale, MAKECONTINTEGRAL, &success) ); } } #endif #endif #ifndef FORCECUTINTEGRAL success = TRUE; #endif if( success ) { if( !SCIPisCutEfficacious(scip, NULL, cut) ) { SCIPdebugMessage(" -> strong CG cut <%s> no longer efficacious: act=%f, rhs=%f, norm=%f, eff=%f\n", cutname, SCIPgetRowLPActivity(scip, cut), SCIProwGetRhs(cut), SCIProwGetNorm(cut), SCIPgetCutEfficacy(scip, NULL, cut)); /*SCIPdebug( SCIP_CALL(SCIPprintRow(scip, cut, NULL)) );*/ success = FALSE; } else { SCIP_Bool infeasible; SCIPdebugMessage(" -> found strong CG cut <%s>: act=%f, rhs=%f, norm=%f, eff=%f, min=%f, max=%f (range=%f)\n", cutname, SCIPgetRowLPActivity(scip, cut), SCIProwGetRhs(cut), SCIProwGetNorm(cut), SCIPgetCutEfficacy(scip, NULL, cut), SCIPgetRowMinCoef(scip, cut), SCIPgetRowMaxCoef(scip, cut), SCIPgetRowMaxCoef(scip, cut)/SCIPgetRowMinCoef(scip, cut)); /*SCIPdebug( SCIP_CALL(SCIPprintRow(scip, cut, NULL)) );*/ SCIP_CALL( SCIPaddCut(scip, NULL, cut, FALSE, &infeasible) ); if ( infeasible ) *result = SCIP_CUTOFF; else { if( !cutislocal ) { SCIP_CALL( SCIPaddPoolCut(scip, cut) ); } *result = SCIP_SEPARATED; } ncuts++; } } else { SCIPdebugMessage(" -> strong CG cut <%s> couldn't be scaled to integral coefficients: act=%f, rhs=%f, norm=%f, eff=%f\n", cutname, cutact, cutrhs, cutnorm, SCIPgetCutEfficacy(scip, NULL, cut)); } /* release the row */ SCIP_CALL( SCIPreleaseRow(scip, &cut) ); } /* free temporary memory */ SCIPfreeBufferArray(scip, &cutvals); SCIPfreeBufferArray(scip, &cutvars); } } } /* free temporary memory */ SCIPfreeBufferArrayNull(scip, &varsolvals); SCIPfreeBufferArray(scip, &inds); SCIPfreeBufferArray(scip, &binvrow); SCIPfreeBufferArray(scip, &basisind); SCIPfreeBufferArray(scip, &cutcoefs); SCIPdebugMessage("end searching strong CG cuts: found %d cuts\n", ncuts); sepadata->lastncutsfound = SCIPgetNCutsFound(scip); return SCIP_OKAY; }
/** LP solution separation method for disjunctive cuts */ static SCIP_DECL_SEPAEXECLP(sepaExeclpDisjunctive) { SCIP_SEPADATA* sepadata; SCIP_CONSHDLR* conshdlr; SCIP_DIGRAPH* conflictgraph; SCIP_ROW** rows; SCIP_COL** cols; SCIP_Real* cutcoefs = NULL; SCIP_Real* simplexcoefs1 = NULL; SCIP_Real* simplexcoefs2 = NULL; SCIP_Real* coef = NULL; SCIP_Real* binvrow = NULL; SCIP_Real* rowsmaxval = NULL; SCIP_Real* violationarray = NULL; int* fixings1 = NULL; int* fixings2 = NULL; int* basisind = NULL; int* basisrow = NULL; int* varrank = NULL; int* edgearray = NULL; int nedges; int ndisjcuts; int nrelevantedges; int nsos1vars; int nconss; int maxcuts; int ncalls; int depth; int ncols; int nrows; int ind; int j; int i; assert( sepa != NULL ); assert( strcmp(SCIPsepaGetName(sepa), SEPA_NAME) == 0 ); assert( scip != NULL ); assert( result != NULL ); *result = SCIP_DIDNOTRUN; /* only generate disjunctive cuts if we are not close to terminating */ if ( SCIPisStopped(scip) ) return SCIP_OKAY; /* only generate disjunctive cuts if an optimal LP solution is at hand */ if ( SCIPgetLPSolstat(scip) != SCIP_LPSOLSTAT_OPTIMAL ) return SCIP_OKAY; /* only generate disjunctive cuts if the LP solution is basic */ if ( ! SCIPisLPSolBasic(scip) ) return SCIP_OKAY; /* get LP data */ SCIP_CALL( SCIPgetLPColsData(scip, &cols, &ncols) ); SCIP_CALL( SCIPgetLPRowsData(scip, &rows, &nrows) ); /* return if LP has no columns or no rows */ if ( ncols == 0 || nrows == 0 ) return SCIP_OKAY; assert( cols != NULL ); assert( rows != NULL ); /* get sepa data */ sepadata = SCIPsepaGetData(sepa); assert( sepadata != NULL ); /* get constraint handler */ conshdlr = sepadata->conshdlr; if ( conshdlr == NULL ) return SCIP_OKAY; /* get number of constraints */ nconss = SCIPconshdlrGetNConss(conshdlr); if ( nconss == 0 ) return SCIP_OKAY; /* check for maxdepth < depth, maxinvcutsroot = 0 and maxinvcuts = 0 */ depth = SCIPgetDepth(scip); if ( ( sepadata->maxdepth >= 0 && sepadata->maxdepth < depth ) || ( depth == 0 && sepadata->maxinvcutsroot == 0 ) || ( depth > 0 && sepadata->maxinvcuts == 0 ) ) return SCIP_OKAY; /* only call the cut separator a given number of times at each node */ ncalls = SCIPsepaGetNCallsAtNode(sepa); if ( (depth == 0 && sepadata->maxroundsroot >= 0 && ncalls >= sepadata->maxroundsroot) || (depth > 0 && sepadata->maxrounds >= 0 && ncalls >= sepadata->maxrounds) ) return SCIP_OKAY; /* get conflict graph and number of conflict graph edges (note that the digraph arcs were added in both directions) */ conflictgraph = SCIPgetConflictgraphSOS1(conshdlr); nedges = (int)SCIPceil(scip, (SCIP_Real)SCIPdigraphGetNArcs(conflictgraph)/2); /* if too many conflict graph edges, the separator can be slow: delay it until no other cuts have been found */ if ( sepadata->maxconfsdelay >= 0 && nedges >= sepadata->maxconfsdelay ) { int ncutsfound; ncutsfound = SCIPgetNCutsFound(scip); if ( ncutsfound > sepadata->lastncutsfound || ! SCIPsepaWasLPDelayed(sepa) ) { sepadata->lastncutsfound = ncutsfound; *result = SCIP_DELAYED; return SCIP_OKAY; } } /* check basis status */ for (j = 0; j < ncols; ++j) { if ( SCIPcolGetBasisStatus(cols[j]) == SCIP_BASESTAT_ZERO ) return SCIP_OKAY; } /* get number of SOS1 variables */ nsos1vars = SCIPgetNSOS1Vars(conshdlr); /* allocate buffer arrays */ SCIP_CALL( SCIPallocBufferArray(scip, &edgearray, nedges) ); SCIP_CALL( SCIPallocBufferArray(scip, &fixings1, nedges) ); SCIP_CALL( SCIPallocBufferArray(scip, &fixings2, nedges) ); SCIP_CALL( SCIPallocBufferArray(scip, &violationarray, nedges) ); /* get all violated conflicts {i, j} in the conflict graph and sort them based on the degree of a violation value */ nrelevantedges = 0; for (j = 0; j < nsos1vars; ++j) { SCIP_VAR* var; var = SCIPnodeGetVarSOS1(conflictgraph, j); if ( SCIPvarIsActive(var) && ! SCIPisFeasZero(scip, SCIPcolGetPrimsol(SCIPvarGetCol(var))) && SCIPcolGetBasisStatus(SCIPvarGetCol(var)) == SCIP_BASESTAT_BASIC ) { int* succ; int nsucc; /* get successors and number of successors */ nsucc = SCIPdigraphGetNSuccessors(conflictgraph, j); succ = SCIPdigraphGetSuccessors(conflictgraph, j); for (i = 0; i < nsucc; ++i) { SCIP_VAR* varsucc; int succind; succind = succ[i]; varsucc = SCIPnodeGetVarSOS1(conflictgraph, succind); if ( SCIPvarIsActive(varsucc) && succind < j && ! SCIPisFeasZero(scip, SCIPgetSolVal(scip, NULL, varsucc) ) && SCIPcolGetBasisStatus(SCIPvarGetCol(varsucc)) == SCIP_BASESTAT_BASIC ) { fixings1[nrelevantedges] = j; fixings2[nrelevantedges] = succind; edgearray[nrelevantedges] = nrelevantedges; violationarray[nrelevantedges++] = SCIPgetSolVal(scip, NULL, var) * SCIPgetSolVal(scip, NULL, varsucc); } } } } /* sort violation score values */ if ( nrelevantedges > 0) SCIPsortDownRealInt(violationarray, edgearray, nrelevantedges); else { SCIPfreeBufferArrayNull(scip, &violationarray); SCIPfreeBufferArrayNull(scip, &fixings2); SCIPfreeBufferArrayNull(scip, &fixings1); SCIPfreeBufferArrayNull(scip, &edgearray); return SCIP_OKAY; } SCIPfreeBufferArrayNull(scip, &violationarray); /* compute maximal number of cuts */ if ( SCIPgetDepth(scip) == 0 ) maxcuts = MIN(sepadata->maxinvcutsroot, nrelevantedges); else maxcuts = MIN(sepadata->maxinvcuts, nrelevantedges); assert( maxcuts > 0 ); /* allocate buffer arrays */ SCIP_CALL( SCIPallocBufferArray(scip, &varrank, ncols) ); SCIP_CALL( SCIPallocBufferArray(scip, &rowsmaxval, nrows) ); SCIP_CALL( SCIPallocBufferArray(scip, &basisrow, ncols) ); SCIP_CALL( SCIPallocBufferArray(scip, &binvrow, nrows) ); SCIP_CALL( SCIPallocBufferArray(scip, &coef, ncols) ); SCIP_CALL( SCIPallocBufferArray(scip, &simplexcoefs1, ncols) ); SCIP_CALL( SCIPallocBufferArray(scip, &simplexcoefs2, ncols) ); SCIP_CALL( SCIPallocBufferArray(scip, &cutcoefs, ncols) ); SCIP_CALL( SCIPallocBufferArray(scip, &basisind, nrows) ); /* get basis indices */ SCIP_CALL( SCIPgetLPBasisInd(scip, basisind) ); /* create vector "basisrow" with basisrow[column of non-slack basis variable] = corresponding row of B^-1; * compute maximum absolute value of nonbasic row coefficients */ for (j = 0; j < nrows; ++j) { SCIP_COL** rowcols; SCIP_Real* rowvals; SCIP_ROW* row; SCIP_Real val; SCIP_Real max = 0.0; int nnonz; /* fill basisrow vector */ ind = basisind[j]; if ( ind >= 0 ) basisrow[ind] = j; /* compute maximum absolute value of nonbasic row coefficients */ row = rows[j]; assert( row != NULL ); rowvals = SCIProwGetVals(row); nnonz = SCIProwGetNNonz(row); rowcols = SCIProwGetCols(row); for (i = 0; i < nnonz; ++i) { if ( SCIPcolGetBasisStatus(rowcols[i]) == SCIP_BASESTAT_LOWER || SCIPcolGetBasisStatus(rowcols[i]) == SCIP_BASESTAT_UPPER ) { val = REALABS(rowvals[i]); if ( SCIPisFeasGT(scip, val, max) ) max = REALABS(val); } } /* handle slack variable coefficient and save maximum value */ rowsmaxval[j] = MAX(max, 1.0); } /* initialize variable ranks with -1 */ for (j = 0; j < ncols; ++j) varrank[j] = -1; /* free buffer array */ SCIPfreeBufferArrayNull(scip, &basisind); /* for the most promising disjunctions: try to generate disjunctive cuts */ ndisjcuts = 0; for (i = 0; i < maxcuts; ++i) { SCIP_Bool madeintegral; SCIP_Real cutlhs1; SCIP_Real cutlhs2; SCIP_Real bound1; SCIP_Real bound2; SCIP_ROW* row = NULL; SCIP_VAR* var; SCIP_COL* col; int nonbasicnumber; int cutrank = 0; int edgenumber; int rownnonz; edgenumber = edgearray[i]; /* determine first simplex row */ var = SCIPnodeGetVarSOS1(conflictgraph, fixings1[edgenumber]); col = SCIPvarGetCol(var); ind = SCIPcolGetLPPos(col); assert( ind >= 0 ); assert( SCIPcolGetBasisStatus(col) == SCIP_BASESTAT_BASIC ); /* get the 'ind'th row of B^-1 and B^-1 \cdot A */ SCIP_CALL( SCIPgetLPBInvRow(scip, basisrow[ind], binvrow, NULL, NULL) ); SCIP_CALL( SCIPgetLPBInvARow(scip, basisrow[ind], binvrow, coef, NULL, NULL) ); /* get the simplex-coefficients of the non-basic variables */ SCIP_CALL( getSimplexCoefficients(scip, rows, nrows, cols, ncols, coef, binvrow, simplexcoefs1, &nonbasicnumber) ); /* get rank of variable if not known already */ if ( varrank[ind] < 0 ) varrank[ind] = getVarRank(scip, binvrow, rowsmaxval, sepadata->maxweightrange, rows, nrows); cutrank = MAX(cutrank, varrank[ind]); /* get right hand side and bound of simplex talbeau row */ cutlhs1 = SCIPcolGetPrimsol(col); if ( SCIPisFeasPositive(scip, cutlhs1) ) bound1 = SCIPcolGetUb(col); else bound1 = SCIPcolGetLb(col); /* determine second simplex row */ var = SCIPnodeGetVarSOS1(conflictgraph, fixings2[edgenumber]); col = SCIPvarGetCol(var); ind = SCIPcolGetLPPos(col); assert( ind >= 0 ); assert( SCIPcolGetBasisStatus(col) == SCIP_BASESTAT_BASIC ); /* get the 'ind'th row of B^-1 and B^-1 \cdot A */ SCIP_CALL( SCIPgetLPBInvRow(scip, basisrow[ind], binvrow, NULL, NULL) ); SCIP_CALL( SCIPgetLPBInvARow(scip, basisrow[ind], binvrow, coef, NULL, NULL) ); /* get the simplex-coefficients of the non-basic variables */ SCIP_CALL( getSimplexCoefficients(scip, rows, nrows, cols, ncols, coef, binvrow, simplexcoefs2, &nonbasicnumber) ); /* get rank of variable if not known already */ if ( varrank[ind] < 0 ) varrank[ind] = getVarRank(scip, binvrow, rowsmaxval, sepadata->maxweightrange, rows, nrows); cutrank = MAX(cutrank, varrank[ind]); /* get right hand side and bound of simplex talbeau row */ cutlhs2 = SCIPcolGetPrimsol(col); if ( SCIPisFeasPositive(scip, cutlhs2) ) bound2 = SCIPcolGetUb(col); else bound2 = SCIPcolGetLb(col); /* add coefficients to cut */ SCIP_CALL( generateDisjCutSOS1(scip, sepa, rows, nrows, cols, ncols, ndisjcuts, TRUE, sepadata->strengthen, cutlhs1, cutlhs2, bound1, bound2, simplexcoefs1, simplexcoefs2, cutcoefs, &row, &madeintegral) ); if ( row == NULL ) continue; /* raise cutrank for present cut */ ++cutrank; /* check if there are numerical evidences */ if ( ( madeintegral && ( sepadata->maxrankintegral == -1 || cutrank <= sepadata->maxrankintegral ) ) || ( ! madeintegral && ( sepadata->maxrank == -1 || cutrank <= sepadata->maxrank ) ) ) { /* possibly add cut to LP if it is useful; in case the lhs of the cut is minus infinity (due to scaling) the cut is useless */ rownnonz = SCIProwGetNNonz(row); if ( rownnonz > 0 && ! SCIPisInfinity(scip, -SCIProwGetLhs(row)) && ! SCIProwIsInLP(row) && SCIPisCutEfficacious(scip, NULL, row) ) { SCIP_Bool infeasible; /* set cut rank */ SCIProwChgRank(row, cutrank); /* add cut */ SCIP_CALL( SCIPaddCut(scip, NULL, row, FALSE, &infeasible) ); SCIPdebug( SCIP_CALL( SCIPprintRow(scip, row, NULL) ) ); if ( infeasible ) { *result = SCIP_CUTOFF; break; } ++ndisjcuts; } } /* release row */ SCIP_CALL( SCIPreleaseRow(scip, &row) ); } /* save total number of cuts found so far */ sepadata->lastncutsfound = SCIPgetNCutsFound(scip); /* evaluate the result of the separation */ if ( *result != SCIP_CUTOFF ) { if ( ndisjcuts > 0 ) *result = SCIP_SEPARATED; else *result = SCIP_DIDNOTFIND; } SCIPdebugMessage("Number of found disjunctive cuts: %d.\n", ndisjcuts); /* free buffer arrays */ SCIPfreeBufferArrayNull(scip, &cutcoefs); SCIPfreeBufferArrayNull(scip, &simplexcoefs2); SCIPfreeBufferArrayNull(scip, &simplexcoefs1); SCIPfreeBufferArrayNull(scip, &coef); SCIPfreeBufferArrayNull(scip, &binvrow); SCIPfreeBufferArrayNull(scip, &basisrow); SCIPfreeBufferArrayNull(scip, &fixings2); SCIPfreeBufferArrayNull(scip, &fixings1); SCIPfreeBufferArrayNull(scip, &edgearray); SCIPfreeBufferArrayNull(scip, &rowsmaxval); SCIPfreeBufferArrayNull(scip, &varrank); return SCIP_OKAY; }
/** LP solution separation method of separator */ static SCIP_DECL_SEPAEXECLP(sepaExeclpRapidlearning) {/*lint --e{715}*/ SCIP* subscip; /* the subproblem created by rapid learning */ SCIP_SEPADATA* sepadata; /* separator's private data */ SCIP_VAR** vars; /* original problem's variables */ SCIP_VAR** subvars; /* subproblem's variables */ SCIP_HASHMAP* varmapfw; /* mapping of SCIP variables to sub-SCIP variables */ SCIP_HASHMAP* varmapbw; /* mapping of sub-SCIP variables to SCIP variables */ SCIP_CONSHDLR** conshdlrs; /* array of constraint handler's that might that might obtain conflicts */ int* oldnconss; /* number of constraints without rapid learning conflicts */ SCIP_Longint nodelimit; /* node limit for the subproblem */ SCIP_Real timelimit; /* time limit for the subproblem */ SCIP_Real memorylimit; /* memory limit for the subproblem */ int nconshdlrs; /* size of conshdlr and oldnconss array */ int nfixedvars; /* number of variables that could be fixed by rapid learning */ int nvars; /* number of variables */ int restartnum; /* maximal number of conflicts that should be created */ int i; /* counter */ SCIP_Bool success; /* was problem creation / copying constraint successful? */ SCIP_RETCODE retcode; /* used for catching sub-SCIP errors in debug mode */ int nconflicts; /* statistic: number of conflicts applied */ int nbdchgs; /* statistic: number of bound changes applied */ int n1startinfers; /* statistic: number of one side infer values */ int n2startinfers; /* statistic: number of both side infer values */ SCIP_Bool soladded; /* statistic: was a new incumbent found? */ SCIP_Bool dualboundchg; /* statistic: was a new dual bound found? */ SCIP_Bool disabledualreductions; /* TRUE, if dual reductions in sub-SCIP are not valid for original SCIP, * e.g., because a constraint could not be copied or a primal solution * could not be copied back */ int ndiscvars; soladded = FALSE; assert(sepa != NULL); assert(scip != NULL); assert(result != NULL); *result = SCIP_DIDNOTRUN; ndiscvars = SCIPgetNBinVars(scip) + SCIPgetNIntVars(scip)+SCIPgetNImplVars(scip); /* only run when still not fixed binary variables exists */ if( ndiscvars == 0 ) return SCIP_OKAY; /* get separator's data */ sepadata = SCIPsepaGetData(sepa); assert(sepadata != NULL); /* only run for integer programs */ if( !sepadata->contvars && ndiscvars != SCIPgetNVars(scip) ) return SCIP_OKAY; /* only run if there are few enough continuous variables */ if( sepadata->contvars && SCIPgetNContVars(scip) > sepadata->contvarsquot * SCIPgetNVars(scip) ) return SCIP_OKAY; /* do not run if pricers are present */ if( SCIPgetNActivePricers(scip) > 0 ) return SCIP_OKAY; /* if the separator should be exclusive to the root node, this prevents multiple calls due to restarts */ if( SCIPsepaGetFreq(sepa) == 0 && SCIPsepaGetNCalls(sepa) > 0) return SCIP_OKAY; /* call separator at most once per node */ if( SCIPsepaGetNCallsAtNode(sepa) > 0 ) return SCIP_OKAY; /* do not call rapid learning, if the problem is too big */ if( SCIPgetNVars(scip) > sepadata->maxnvars || SCIPgetNConss(scip) > sepadata->maxnconss ) return SCIP_OKAY; if( SCIPisStopped(scip) ) return SCIP_OKAY; *result = SCIP_DIDNOTFIND; SCIP_CALL( SCIPgetVarsData(scip, &vars, &nvars, NULL, NULL, NULL, NULL) ); /* initializing the subproblem */ SCIP_CALL( SCIPallocBufferArray(scip, &subvars, nvars) ); SCIP_CALL( SCIPcreate(&subscip) ); SCIP_CALL( SCIPhashmapCreate(&varmapfw, SCIPblkmem(subscip), SCIPcalcHashtableSize(5 * nvars)) ); success = FALSE; /* copy the subproblem */ SCIP_CALL( SCIPcopy(scip, subscip, varmapfw, NULL, "rapid", FALSE, FALSE, &success) ); if( sepadata->copycuts ) { /** copies all active cuts from cutpool of sourcescip to linear constraints in targetscip */ SCIP_CALL( SCIPcopyCuts(scip, subscip, varmapfw, NULL, FALSE) ); } for( i = 0; i < nvars; i++ ) subvars[i] = (SCIP_VAR*) (size_t) SCIPhashmapGetImage(varmapfw, vars[i]); SCIPhashmapFree(&varmapfw); /* this avoids dual presolving */ if( !success ) { for( i = 0; i < nvars; i++ ) { SCIP_CALL( SCIPaddVarLocks(subscip, subvars[i], 1, 1 ) ); } } SCIPdebugMessage("Copying SCIP was%s successful.\n", success ? "" : " not"); /* mimic an FD solver: DFS, no LP solving, 1-FUIP instead of all-FUIP */ SCIP_CALL( SCIPsetIntParam(subscip, "lp/solvefreq", -1) ); SCIP_CALL( SCIPsetIntParam(subscip, "conflict/fuiplevels", 1) ); SCIP_CALL( SCIPsetIntParam(subscip, "nodeselection/dfs/stdpriority", INT_MAX/4) ); SCIP_CALL( SCIPsetBoolParam(subscip, "constraints/disableenfops", TRUE) ); SCIP_CALL( SCIPsetIntParam(subscip, "propagating/pseudoobj/freq", -1) ); /* use inference branching */ SCIP_CALL( SCIPsetBoolParam(subscip, "branching/inference/useweightedsum", FALSE) ); /* only create short conflicts */ SCIP_CALL( SCIPsetRealParam(subscip, "conflict/maxvarsfac", 0.05) ); /* set limits for the subproblem */ nodelimit = SCIPgetNLPIterations(scip); nodelimit = MAX(sepadata->minnodes, nodelimit); nodelimit = MIN(sepadata->maxnodes, nodelimit); restartnum = 1000; /* check whether there is enough time and memory left */ SCIP_CALL( SCIPgetRealParam(scip, "limits/time", &timelimit) ); if( !SCIPisInfinity(scip, timelimit) ) timelimit -= SCIPgetSolvingTime(scip); SCIP_CALL( SCIPgetRealParam(scip, "limits/memory", &memorylimit) ); if( !SCIPisInfinity(scip, memorylimit) ) memorylimit -= SCIPgetMemUsed(scip)/1048576.0; if( timelimit <= 0.0 || memorylimit <= 0.0 ) goto TERMINATE; SCIP_CALL( SCIPsetLongintParam(subscip, "limits/nodes", nodelimit/5) ); SCIP_CALL( SCIPsetRealParam(subscip, "limits/time", timelimit) ); SCIP_CALL( SCIPsetRealParam(subscip, "limits/memory", memorylimit) ); SCIP_CALL( SCIPsetIntParam(subscip, "limits/restarts", 0) ); SCIP_CALL( SCIPsetIntParam(subscip, "conflict/restartnum", restartnum) ); /* forbid recursive call of heuristics and separators solving subMIPs */ SCIP_CALL( SCIPsetSubscipsOff(subscip, TRUE) ); /* disable cutting plane separation */ SCIP_CALL( SCIPsetSeparating(subscip, SCIP_PARAMSETTING_OFF, TRUE) ); /* disable expensive presolving */ SCIP_CALL( SCIPsetPresolving(subscip, SCIP_PARAMSETTING_FAST, TRUE) ); /* do not abort subproblem on CTRL-C */ SCIP_CALL( SCIPsetBoolParam(subscip, "misc/catchctrlc", FALSE) ); #ifndef SCIP_DEBUG /* disable output to console */ SCIP_CALL( SCIPsetIntParam(subscip, "display/verblevel", 0) ); #endif /* add an objective cutoff */ SCIP_CALL( SCIPsetObjlimit(subscip, SCIPgetUpperbound(scip)) ); /* create the variable mapping hash map */ SCIP_CALL( SCIPhashmapCreate(&varmapbw, SCIPblkmem(scip), SCIPcalcHashtableSize(5 * nvars)) ); /* store reversing mapping of variables */ SCIP_CALL( SCIPtransformProb(subscip) ); for( i = 0; i < nvars; ++i) { SCIP_CALL( SCIPhashmapInsert(varmapbw, SCIPvarGetTransVar(subvars[i]), vars[i]) ); } /** allocate memory for constraints storage. Each constraint that will be created from now on will be a conflict. * Therefore, we need to remember oldnconss to get the conflicts from the FD search. */ nconshdlrs = 4; SCIP_CALL( SCIPallocBufferArray(scip, &conshdlrs, nconshdlrs) ); SCIP_CALL( SCIPallocBufferArray(scip, &oldnconss, nconshdlrs) ); /* store number of constraints before rapid learning search */ conshdlrs[0] = SCIPfindConshdlr(subscip, "bounddisjunction"); conshdlrs[1] = SCIPfindConshdlr(subscip, "setppc"); conshdlrs[2] = SCIPfindConshdlr(subscip, "linear"); conshdlrs[3] = SCIPfindConshdlr(subscip, "logicor"); /* redundant constraints might be eliminated in presolving */ SCIP_CALL( SCIPpresolve(subscip)); for( i = 0; i < nconshdlrs; ++i) { if( conshdlrs[i] != NULL ) oldnconss[i] = SCIPconshdlrGetNConss(conshdlrs[i]); } nfixedvars = SCIPgetNFixedVars(scip); /* solve the subproblem */ retcode = SCIPsolve(subscip); /* Errors in solving the subproblem should not kill the overall solving process * Hence, the return code is caught and a warning is printed, only in debug mode, SCIP will stop. */ if( retcode != SCIP_OKAY ) { #ifndef NDEBUG SCIP_CALL( retcode ); #endif SCIPwarningMessage("Error while solving subproblem in rapid learning separator; sub-SCIP terminated with code <%d>\n",retcode); } /* abort solving, if limit of applied conflicts is reached */ if( SCIPgetNConflictConssApplied(subscip) >= restartnum ) { SCIPdebugMessage("finish after %lld successful conflict calls.\n", SCIPgetNConflictConssApplied(subscip)); } /* if the first 20% of the solution process were successful, proceed */ else if( (sepadata->applyprimalsol && SCIPgetNSols(subscip) > 0 && SCIPisFeasLT(scip, SCIPgetUpperbound(subscip), SCIPgetUpperbound(scip) ) ) || (sepadata->applybdchgs && SCIPgetNFixedVars(subscip) > nfixedvars) || (sepadata->applyconflicts && SCIPgetNConflictConssApplied(subscip) > 0) ) { SCIPdebugMessage("proceed solving after the first 20%% of the solution process, since:\n"); if( SCIPgetNSols(subscip) > 0 && SCIPisFeasLE(scip, SCIPgetUpperbound(subscip), SCIPgetUpperbound(scip) ) ) { SCIPdebugMessage(" - there was a better solution (%f < %f)\n",SCIPgetUpperbound(subscip), SCIPgetUpperbound(scip)); } if( SCIPgetNFixedVars(subscip) > nfixedvars ) { SCIPdebugMessage(" - there were %d variables fixed\n", SCIPgetNFixedVars(scip)-nfixedvars ); } if( SCIPgetNConflictConssFound(subscip) > 0 ) { SCIPdebugMessage(" - there were %lld conflict constraints created\n", SCIPgetNConflictConssApplied(subscip)); } /* set node limit to 100% */ SCIP_CALL( SCIPsetLongintParam(subscip, "limits/nodes", nodelimit) ); /* solve the subproblem */ retcode = SCIPsolve(subscip); /* Errors in solving the subproblem should not kill the overall solving process * Hence, the return code is caught and a warning is printed, only in debug mode, SCIP will stop. */ if( retcode != SCIP_OKAY ) { #ifndef NDEBUG SCIP_CALL( retcode ); #endif SCIPwarningMessage("Error while solving subproblem in rapid learning separator; sub-SCIP terminated with code <%d>\n",retcode); } } else { SCIPdebugMessage("do not proceed solving after the first 20%% of the solution process.\n"); } #ifdef SCIP_DEBUG SCIP_CALL( SCIPprintStatistics(subscip, NULL) ); #endif disabledualreductions = FALSE; /* check, whether a solution was found */ if( sepadata->applyprimalsol && SCIPgetNSols(subscip) > 0 && SCIPfindHeur(scip, "trysol") != NULL ) { SCIP_HEUR* heurtrysol; SCIP_SOL** subsols; int nsubsols; /* check, whether a solution was found; * due to numerics, it might happen that not all solutions are feasible -> try all solutions until was declared to be feasible */ nsubsols = SCIPgetNSols(subscip); subsols = SCIPgetSols(subscip); soladded = FALSE; heurtrysol = SCIPfindHeur(scip, "trysol"); /* sequentially add solutions to trysol heuristic */ for( i = 0; i < nsubsols && !soladded; ++i ) { SCIPdebugMessage("Try to create new solution by copying subscip solution.\n"); SCIP_CALL( createNewSol(scip, subscip, subvars, heurtrysol, subsols[i], &soladded) ); } if( !soladded || !SCIPisEQ(scip, SCIPgetSolOrigObj(subscip, subsols[i-1]), SCIPgetSolOrigObj(subscip, subsols[0])) ) disabledualreductions = TRUE; } /* if the sub problem was solved completely, we update the dual bound */ dualboundchg = FALSE; if( sepadata->applysolved && !disabledualreductions && (SCIPgetStatus(subscip) == SCIP_STATUS_OPTIMAL || SCIPgetStatus(subscip) == SCIP_STATUS_INFEASIBLE) ) { /* we need to multiply the dualbound with the scaling factor and add the offset, * because this information has been disregarded in the sub-SCIP */ SCIPdebugMessage("Update old dualbound %g to new dualbound %g.\n", SCIPgetDualbound(scip), SCIPgetTransObjscale(scip) * SCIPgetDualbound(subscip) + SCIPgetTransObjoffset(scip)); SCIP_CALL( SCIPupdateLocalDualbound(scip, SCIPgetDualbound(subscip) * SCIPgetTransObjscale(scip) + SCIPgetTransObjoffset(scip)) ); dualboundchg = TRUE; } /* check, whether conflicts were created */ nconflicts = 0; if( sepadata->applyconflicts && !disabledualreductions && SCIPgetNConflictConssApplied(subscip) > 0 ) { SCIP_HASHMAP* consmap; int hashtablesize; assert(SCIPgetNConflictConssApplied(subscip) < (SCIP_Longint) INT_MAX); hashtablesize = (int) SCIPgetNConflictConssApplied(subscip); assert(hashtablesize < INT_MAX/5); hashtablesize *= 5; /* create the variable mapping hash map */ SCIP_CALL( SCIPhashmapCreate(&consmap, SCIPblkmem(scip), SCIPcalcHashtableSize(hashtablesize)) ); /* loop over all constraint handlers that might contain conflict constraints */ for( i = 0; i < nconshdlrs; ++i) { /* copy constraints that have been created in FD run */ if( conshdlrs[i] != NULL && SCIPconshdlrGetNConss(conshdlrs[i]) > oldnconss[i] ) { SCIP_CONS** conss; int c; int nconss; nconss = SCIPconshdlrGetNConss(conshdlrs[i]); conss = SCIPconshdlrGetConss(conshdlrs[i]); /* loop over all constraints that have been added in sub-SCIP run, these are the conflicts */ for( c = oldnconss[i]; c < nconss; ++c) { SCIP_CONS* cons; SCIP_CONS* conscopy; cons = conss[c]; assert(cons != NULL); success = FALSE; SCIP_CALL( SCIPgetConsCopy(subscip, scip, cons, &conscopy, conshdlrs[i], varmapbw, consmap, NULL, SCIPconsIsInitial(cons), SCIPconsIsSeparated(cons), SCIPconsIsEnforced(cons), SCIPconsIsChecked(cons), SCIPconsIsPropagated(cons), TRUE, FALSE, SCIPconsIsDynamic(cons), SCIPconsIsRemovable(cons), FALSE, TRUE, &success) ); if( success ) { nconflicts++; SCIP_CALL( SCIPaddCons(scip, conscopy) ); SCIP_CALL( SCIPreleaseCons(scip, &conscopy) ); } else { SCIPdebugMessage("failed to copy conflict constraint %s back to original SCIP\n", SCIPconsGetName(cons)); } } } } SCIPhashmapFree(&consmap); } /* check, whether tighter global bounds were detected */ nbdchgs = 0; if( sepadata->applybdchgs && !disabledualreductions ) for( i = 0; i < nvars; ++i ) { SCIP_Bool infeasible; SCIP_Bool tightened; assert(SCIPisLE(scip, SCIPvarGetLbGlobal(vars[i]), SCIPvarGetLbGlobal(subvars[i]))); assert(SCIPisLE(scip, SCIPvarGetLbGlobal(subvars[i]), SCIPvarGetUbGlobal(subvars[i]))); assert(SCIPisLE(scip, SCIPvarGetUbGlobal(subvars[i]), SCIPvarGetUbGlobal(vars[i]))); /* update the bounds of the original SCIP, if a better bound was proven in the sub-SCIP */ SCIP_CALL( SCIPtightenVarUb(scip, vars[i], SCIPvarGetUbGlobal(subvars[i]), FALSE, &infeasible, &tightened) ); if( tightened ) nbdchgs++; SCIP_CALL( SCIPtightenVarLb(scip, vars[i], SCIPvarGetLbGlobal(subvars[i]), FALSE, &infeasible, &tightened) ); if( tightened ) nbdchgs++; } n1startinfers = 0; n2startinfers = 0; /* install start values for inference branching */ if( sepadata->applyinfervals && (!sepadata->reducedinfer || soladded || nbdchgs+nconflicts > 0) ) { for( i = 0; i < nvars; ++i ) { SCIP_Real downinfer; SCIP_Real upinfer; SCIP_Real downvsids; SCIP_Real upvsids; SCIP_Real downconflen; SCIP_Real upconflen; /* copy downwards branching statistics */ downvsids = SCIPgetVarVSIDS(subscip, subvars[i], SCIP_BRANCHDIR_DOWNWARDS); downconflen = SCIPgetVarAvgConflictlength(subscip, subvars[i], SCIP_BRANCHDIR_DOWNWARDS); downinfer = SCIPgetVarAvgInferences(subscip, subvars[i], SCIP_BRANCHDIR_DOWNWARDS); /* copy upwards branching statistics */ upvsids = SCIPgetVarVSIDS(subscip, subvars[i], SCIP_BRANCHDIR_UPWARDS); upconflen = SCIPgetVarAvgConflictlength(subscip, subvars[i], SCIP_BRANCHDIR_UPWARDS); upinfer = SCIPgetVarAvgInferences(subscip, subvars[i], SCIP_BRANCHDIR_UPWARDS); /* memorize statistics */ if( downinfer+downconflen+downvsids > 0.0 || upinfer+upconflen+upvsids != 0 ) n1startinfers++; if( downinfer+downconflen+downvsids > 0.0 && upinfer+upconflen+upvsids != 0 ) n2startinfers++; SCIP_CALL( SCIPinitVarBranchStats(scip, vars[i], 0.0, 0.0, downvsids, upvsids, downconflen, upconflen, downinfer, upinfer, 0.0, 0.0) ); } } SCIPdebugPrintf("XXX Rapidlearning added %d conflicts, changed %d bounds, %s primal solution, %s dual bound improvement.\n", nconflicts, nbdchgs, soladded ? "found" : "no", dualboundchg ? "found" : "no"); SCIPdebugPrintf("YYY Infervalues initialized on one side: %5.2f %% of variables, %5.2f %% on both sides\n", 100.0 * n1startinfers/(SCIP_Real)nvars, 100.0 * n2startinfers/(SCIP_Real)nvars); /* change result pointer */ if( nconflicts > 0 || dualboundchg ) *result = SCIP_CONSADDED; else if( nbdchgs > 0 ) *result = SCIP_REDUCEDDOM; /* free local data */ SCIPfreeBufferArray(scip, &oldnconss); SCIPfreeBufferArray(scip, &conshdlrs); SCIPhashmapFree(&varmapbw); TERMINATE: /* free subproblem */ SCIPfreeBufferArray(scip, &subvars); SCIP_CALL( SCIPfree(&subscip) ); return SCIP_OKAY; }