/** returns a score value for the given variable based on the active constraints that the variable appears in */
static
SCIP_Real getNActiveConsScore(
SCIP* scip, /**< SCIP data structure */
SCIP_VAR* var, /**< variable to get the score value for */
SCIP_Real* downscore, /**< pointer to store the score for branching downwards */
SCIP_Real* upscore /**< pointer to store the score for branching upwards */
)
{
SCIP_COL* col;
SCIP_ROW** rows;
SCIP_Real* vals;
int nrows;
int r;
int nactrows;
SCIP_Real downcoefsum;
SCIP_Real upcoefsum;
SCIP_Real score;
assert(downscore != NULL);
assert(upscore != NULL);
*downscore = 0.0;
*upscore = 0.0;
if( SCIPvarGetStatus(var) != SCIP_VARSTATUS_COLUMN )
return 0.0;
col = SCIPvarGetCol(var);
assert(col != NULL);
rows = SCIPcolGetRows(col);
vals = SCIPcolGetVals(col);
nrows = SCIPcolGetNLPNonz(col);
nactrows = 0;
downcoefsum = 0.0;
upcoefsum = 0.0;
for( r = 0; r < nrows; ++r )
{
SCIP_Real activity;
SCIP_Real lhs;
SCIP_Real rhs;
SCIP_Real dualsol;
/* calculate number of active constraint sides, i.e., count equations as two */
lhs = SCIProwGetLhs(rows[r]);
rhs = SCIProwGetRhs(rows[r]);
activity = SCIPgetRowLPActivity(scip, rows[r]);
dualsol = SCIProwGetDualsol(rows[r]);
if( SCIPisFeasEQ(scip, activity, lhs) )
{
SCIP_Real coef;
nactrows++;
coef = vals[r] / SCIProwGetNorm(rows[r]);
if( SCIPisFeasPositive(scip, dualsol) )
{
if( coef > 0.0 )
downcoefsum += coef;
else
upcoefsum -= coef;
}
}
else if( SCIPisFeasEQ(scip, activity, rhs) )
{
SCIP_Real coef;
nactrows++;
coef = vals[r] / SCIProwGetNorm(rows[r]);
if( SCIPisFeasNegative(scip, dualsol) )
{
if( coef > 0.0 )
upcoefsum += coef;
else
downcoefsum -= coef;
}
}
}
score = 1e-3*nactrows + (downcoefsum + 1e-6) * (upcoefsum + 1e-6);
*downscore = -downcoefsum;
*upscore = -upcoefsum;
return score;
}
/** generates the direction of the shooting ray as the average of the normalized non-basic vars and rows */
static
SCIP_RETCODE generateAverageNBRay(
SCIP* scip, /**< SCIP data structure */
SCIP_Real* raydirection, /**< shooting ray */
int* fracspace, /**< index set of fractional variables */
SCIP_VAR** subspacevars, /**< pointer to fractional space variables */
int nsubspacevars /**< dimension of fractional space */
)
{
SCIP_ROW** rows;
SCIP_COL** cols;
int nrows;
int ncols;
int i;
assert(scip != NULL);
assert(raydirection != NULL);
assert(fracspace != NULL);
assert(subspacevars != NULL);
SCIP_CALL( SCIPgetLPRowsData(scip, &rows, &nrows) );
SCIP_CALL( SCIPgetLPColsData(scip, &cols, &ncols) );
/* add up non-basic variables */
for( i = nsubspacevars - 1; i >= 0; --i )
{
SCIP_Real solval;
solval = SCIPvarGetLPSol(subspacevars[i]);
if( SCIPisFeasEQ(scip, solval, SCIPvarGetLbLocal(subspacevars[i])) )
raydirection[i] = +1.0;
else if( SCIPisFeasEQ(scip, solval, SCIPvarGetUbLocal(subspacevars[i])) )
raydirection[i] = -1.0;
else
raydirection[i] = 0.0;
}
/* add up non-basic rows */
for( i = nrows - 1; i >= 0; --i )
{
SCIP_Real dualsol;
SCIP_Real factor;
SCIP_Real* coeffs;
SCIP_Real rownorm;
int j;
int nnonz;
dualsol = SCIProwGetDualsol(rows[i]);
if( SCIPisFeasPositive(scip, dualsol) )
factor = 1.0;
else if( SCIPisFeasNegative(scip, dualsol) )
factor = -1.0;
else
continue;
/* get the row's data */
coeffs = SCIProwGetVals(rows[i]);
cols = SCIProwGetCols(rows[i]);
nnonz = SCIProwGetNNonz(rows[i]);
rownorm = 0.0;
for( j = nnonz - 1; j >= 0; --j )
{
SCIP_VAR* var;
var = SCIPcolGetVar(cols[j]);
if( fracspace[SCIPvarGetProbindex(var)] >= 0 )
rownorm += coeffs[j] * coeffs[j];
}
if( SCIPisFeasZero(scip,rownorm) )
continue;
else
{
assert(rownorm > 0);
rownorm = SQRT(rownorm);
}
for( j = nnonz - 1; j >= 0; --j )
{
SCIP_VAR* var;
int f;
var = SCIPcolGetVar(cols[j]);
f = fracspace[SCIPvarGetProbindex(var)];
if( f >= 0 )
{
raydirection[f] += factor * coeffs[j] / rownorm;
assert(SCIP_REAL_MIN <= raydirection[f] && raydirection[f] <= SCIP_REAL_MAX);
}
}
}
return SCIP_OKAY;
}
/** returns a score value for the given variable based on the active constraints that the variable appears in */
static
SCIP_Real getNActiveConsScore(
SCIP* scip, /**< SCIP data structure */
SCIP_SOL* sol, /**< working solution */
SCIP_VAR* var, /**< variable to get the score value for */
SCIP_Real* downscore, /**< pointer to store the score for branching downwards */
SCIP_Real* upscore /**< pointer to store the score for branching upwards */
)
{
SCIP_COL* col;
SCIP_ROW** rows;
SCIP_Real* vals;
int nrows;
int r;
int nactrows;
SCIP_Real nlprows;
SCIP_Real downcoefsum;
SCIP_Real upcoefsum;
SCIP_Real score;
assert(downscore != NULL);
assert(upscore != NULL);
*downscore = 0.0;
*upscore = 0.0;
if( SCIPvarGetStatus(var) != SCIP_VARSTATUS_COLUMN )
return 0.0;
col = SCIPvarGetCol(var);
assert(col != NULL);
rows = SCIPcolGetRows(col);
vals = SCIPcolGetVals(col);
nrows = SCIPcolGetNLPNonz(col);
nactrows = 0;
downcoefsum = 0.0;
upcoefsum = 0.0;
for( r = 0; r < nrows; ++r )
{
SCIP_ROW* row;
SCIP_Real activity;
SCIP_Real lhs;
SCIP_Real rhs;
SCIP_Real dualsol;
row = rows[r];
/* calculate number of active constraint sides, i.e., count equations as two */
lhs = SCIProwGetLhs(row);
rhs = SCIProwGetRhs(row);
/* @todo this is suboptimal because activity is calculated by looping over all nonzeros of this row, need to
* store LP activities instead (which cannot be retrieved if no LP was solved at this node)
*/
activity = SCIPgetRowSolActivity(scip, row, sol);
dualsol = SCIProwGetDualsol(row);
if( SCIPisFeasEQ(scip, activity, lhs) )
{
SCIP_Real coef;
nactrows++;
coef = vals[r] / SCIProwGetNorm(row);
if( SCIPisFeasPositive(scip, dualsol) )
{
if( coef > 0.0 )
downcoefsum += coef;
else
upcoefsum -= coef;
}
}
else if( SCIPisFeasEQ(scip, activity, rhs) )
{
SCIP_Real coef;
nactrows++;
coef = vals[r] / SCIProwGetNorm(row);
if( SCIPisFeasNegative(scip, dualsol) )
{
if( coef > 0.0 )
upcoefsum += coef;
else
downcoefsum -= coef;
}
}
}
/* use the number of LP rows for normalization */
nlprows = (SCIP_Real)SCIPgetNLPRows(scip);
upcoefsum /= nlprows;
downcoefsum /= nlprows;
/* calculate the score using SCIP's branch score. Pass NULL as variable to not have the var branch factor influence
* the result
*/
score = nactrows / nlprows + SCIPgetBranchScore(scip, NULL, downcoefsum, upcoefsum);
assert(score <= 3.0);
assert(score >= 0.0);
*downscore = downcoefsum;
*upscore = upcoefsum;
return score;
}
/** generates the direction of the shooting ray as the average of the extreme rays of the basic cone */
static
SCIP_RETCODE generateAverageRay(
SCIP* scip, /**< SCIP data structure */
SCIP_Real* raydirection, /**< shooting ray */
SCIP_VAR** subspacevars, /**< pointer to fractional space variables */
int nsubspacevars, /**< dimension of fractional space */
SCIP_Bool weighted /**< should the rays be weighted? */
)
{
SCIP_ROW** rows;
SCIP_Real** tableaurows;
SCIP_Real* rownorm;
SCIP_Real rowweight;
int nrows;
int i;
int j;
assert(scip != NULL);
assert(raydirection != NULL);
assert(subspacevars != NULL);
/* get data */
SCIP_CALL( SCIPgetLPRowsData(scip, &rows, &nrows) );
/* allocate memory */
SCIP_CALL( SCIPallocBufferArray(scip, &tableaurows, nsubspacevars) );
for( j = nsubspacevars - 1; j >= 0; --j )
{
/*lint --e{866}*/
SCIP_CALL( SCIPallocBufferArray(scip, &tableaurows[j], nrows) );
}
SCIP_CALL( SCIPallocBufferArray(scip, &rownorm, nrows) );
for( i = nrows - 1; i >= 0; --i )
rownorm[i] = 0;
/* get the relevant columns of the simplex tableau */
for( j = nsubspacevars-1; j >= 0; --j )
{
assert(SCIPcolGetLPPos(SCIPvarGetCol(subspacevars[j])) >= 0);
SCIP_CALL( SCIPgetLPBInvACol(scip, SCIPcolGetLPPos(SCIPvarGetCol(subspacevars[j])), tableaurows[j]) );
for( i = nrows - 1; i >= 0; --i )
rownorm[i] += tableaurows[j][i] * tableaurows[j][i];
}
/* take average over all rows of the tableau */
for( i = nrows - 1; i >= 0; --i )
{
if( SCIPisFeasZero(scip, rownorm[i]) )
continue;
else
rownorm[i] = SQRT(rownorm[i]);
rowweight = 0.0;
if( weighted )
{
rowweight = SCIProwGetDualsol(rows[i]);
if( SCIPisFeasZero(scip, rowweight) )
continue;
}
else
rowweight = 1.0;
for( j = nsubspacevars - 1; j >= 0; --j )
{
raydirection[j] += tableaurows[j][i] / (rownorm[i] * rowweight);
assert(SCIP_REAL_MIN <= raydirection[j] && raydirection[j] <= SCIP_REAL_MAX);
}
}
/* free memory */
SCIPfreeBufferArray(scip, &rownorm);
for( j = nsubspacevars - 1; j >= 0; --j )
{
SCIPfreeBufferArray(scip, &tableaurows[j]);
}
SCIPfreeBufferArray(scip, &tableaurows);
return SCIP_OKAY;
}
