/* $Id$ */ // Copyright (C) 2002, International Business Machines // Corporation and others. All Rights Reserved. // This code is licensed under the terms of the Eclipse Public License (EPL). #include #include #include "CoinHelperFunctions.hpp" #include "CoinPresolveMatrix.hpp" #include "CoinPresolveEmpty.hpp" // for DROP_COL/DROP_ROW #include "CoinPresolveFixed.hpp" #include "CoinPresolveSingleton.hpp" #if PRESOLVE_DEBUG > 0 || PRESOLVE_CONSISTENCY > 0 #include "CoinPresolvePsdebug.hpp" #endif #include "CoinMessage.hpp" #include "CoinFinite.hpp" /* * Original comment: * * Transfers singleton row bound information to the corresponding column bounds. * What I refer to as a row singleton would be called a doubleton * in the paper, since my terminology doesn't refer to the slacks. * In terms of the paper, we transfer the bounds of the slack onto * the variable (vii) and then "substitute" the slack out of the problem * (which is a noop). */ /* Given blow(i) <= a(ij)x(j) <= b(i), we can transfer the bounds enforced by the constraint to the column bounds l(j) and u(j) on x(j) and delete the row. You can think of this as a specialised instance of doubleton_action, where the target variable is the logical that transforms an inequality to an equality. Since the system doesn't have logicals at this point, the row is a singleton. At some time in the past, the main loop was written to scan all rows but was limited in the number of rows it could process in one call. The notFinished parameter is the only remaining vestige of this behaviour and should probably be removed. For now, make sure it's forced to false for the benefit of code that looks at the returned value. -- lh, 121015 -- */ const CoinPresolveAction * slack_doubleton_action::presolve(CoinPresolveMatrix *prob, const CoinPresolveAction *next, bool ¬Finished) { # if PRESOLVE_DEBUG > 0 || PRESOLVE_CONSISTENCY > 0 # if PRESOLVE_DEBUG > 0 std::cout << "Entering slack_doubleton_action::presolve." << std::endl ; # endif # if PRESOLVE_CONSISTENCY > 0 presolve_consistent(prob) ; presolve_links_ok(prob) ; presolve_check_sol(prob) ; presolve_check_nbasic(prob) ; # endif # endif # if PRESOLVE_DEBUG > 0 || COIN_PRESOLVE_TUNING > 0 int startEmptyRows = prob->countEmptyRows() ; int startEmptyColumns = prob->countEmptyCols() ; # if COIN_PRESOLVE_TUNING > 0 double startTime = 0.0 ; if (prob->tuning_) { startTime = CoinCpuTime() ; } # endif # endif notFinished = false ; /* Unpack the problem representation. */ double *colels = prob->colels_ ; int *hrow = prob->hrow_ ; CoinBigIndex *mcstrt = prob->mcstrt_ ; int *hincol = prob->hincol_ ; double *clo = prob->clo_ ; double *cup = prob->cup_ ; double *rowels = prob->rowels_ ; const int *hcol = prob->hcol_ ; const CoinBigIndex *mrstrt = prob->mrstrt_ ; int *hinrow = prob->hinrow_ ; double *rlo = prob->rlo_ ; double *rup = prob->rup_ ; /* Rowstat is used to decide if the solution is present. */ unsigned char *rowstat = prob->rowstat_ ; double *acts = prob->acts_ ; double *sol = prob->sol_ ; const unsigned char *integerType = prob->integerType_ ; const double ztolzb = prob->ztolzb_ ; int numberLook = prob->numberRowsToDo_ ; int *look = prob->rowsToDo_ ; bool fixInfeasibility = ((prob->presolveOptions_&0x4000) != 0) ; action *actions = new action[numberLook] ; int nactions = 0 ; int *fixed_cols = prob->usefulColumnInt_ ; int nfixed_cols = 0 ; bool infeas = false ; /* Walk the rows looking for singletons. */ for (int iLook = 0 ; iLook < numberLook ; iLook++) { int i = look[iLook] ; if (hinrow[i] != 1) continue ; int j = hcol[mrstrt[i]] ; double aij = rowels[mrstrt[i]] ; double lo = rlo[i] ; double up = rup[i] ; double abs_aij = fabs(aij) ; /* A tiny value of a(ij) invites numerical error, since the new bound will be (something)/a(ij). Columns that are already fixed are also uninteresting. */ if (abs_aij < ZTOLDP2) continue ; if (fabs(cup[j]-clo[j]) < ztolzb) continue ; PRESOLVE_DETAIL_PRINT(printf("pre_singleton %dC %dR E\n",j,i)) ; /* Get down to work. First create the postsolve action for row i / x(j). */ action *s = &actions[nactions] ; nactions++ ; s->col = j ; s->clo = clo[j] ; s->cup = cup[j] ; s->row = i ; s->rlo = rlo[i] ; s->rup = rup[i] ; s->coeff = aij ; # if PRESOLVE_DEBUG > 1 std::cout << " removing row " << i << ": " << rlo[i] << " <= " << aij << "*x(" << j << ") <= " << rup[i] << std::endl ; # endif /* Do the work of bounds transfer. Starting with blow(i) <= a(ij)x(j) <= b(i), we end up with blow(i)/a(ij) <= x(j) <= b(i)/a(ij) a(ij) > 0 blow(i)/a(ij) >= x(j) >= b(i)/a(ij) a(ij) < 0 The code deals with a(ij) < 0 by swapping and negating the row bounds and calculating with |a(ij)|. Be careful not to convert finite infinity to finite, or vice versa. */ if (aij < 0.0) { CoinSwap(lo,up) ; lo = -lo ; up = -up ; } if (lo <= -PRESOLVE_INF) lo = -PRESOLVE_INF ; else { lo /= abs_aij ; if (lo <= -PRESOLVE_INF) lo = -PRESOLVE_INF ; } if (up > PRESOLVE_INF) up = PRESOLVE_INF ; else { up /= abs_aij ; if (up > PRESOLVE_INF) up = PRESOLVE_INF ; } # if PRESOLVE_DEBUG > 2 std::cout << " l(" << j << ") = " << clo[j] << " ==> " << lo << ", delta " << (lo-clo[j]) << std::endl ; std::cout << " u(" << j << ") = " << cup[j] << " ==> " << up << ", delta " << (cup[j]-up) << std::endl ; # endif /* lo and up are now the new l(j) and u(j), respectively. If they're better than the existing bounds, update. Have a care with integer variables --- don't let numerical inaccuracy pull us off an integral bound. */ if (clo[j] < lo) { // If integer be careful if (integerType[j]) { if (fabs(lo-floor(lo+0.5)) < 0.000001) lo = floor(lo+0.5) ; if (clo[j] < lo) clo[j] = lo ; } else { clo[j] = lo ; } } if (cup[j] > up) { if (integerType[j]) { if (fabs(up-floor(up+0.5)) < 0.000001) up = floor(up+0.5) ; if (cup[j] > up) cup[j] = up ; } else { cup[j] = up ; } } /* Is x(j) now fixed? Remember it for later. */ if (fabs(cup[j] - clo[j]) < ZTOLDP) { fixed_cols[nfixed_cols++] = j ; } /* Is x(j) infeasible? Fix it if we're within the feasibility tolerance, or if the user was so foolish as to request repair of infeasibility. Integer values are preferred, if close enough. If the infeasibility is too large to ignore, mark the problem infeasible and head for the exit. */ if (lo > up) { if (lo <= up+prob->feasibilityTolerance_ || fixInfeasibility) { double nearest = floor(lo+0.5) ; if (fabs(nearest-lo)<2.0*prob->feasibilityTolerance_) { lo = nearest ; up = nearest ; } else { lo = up ; } clo[j] = lo ; cup[j] = up ; } else { prob->status_ |= 1 ; prob->messageHandler()->message(COIN_PRESOLVE_COLINFEAS, prob->messages()) << j << lo << up << CoinMessageEol ; infeas = true ; break ; } } # if PRESOLVE_DEBUG > 1 printf("SINGLETON R-%d C-%d\n", i, j) ; # endif /* Remove the row from the row-major representation. */ hinrow[i] = 0 ; PRESOLVE_REMOVE_LINK(prob->rlink_,i) ; rlo[i] = 0.0 ; rup[i] = 0.0 ; /* Remove the row from this col in the column-major representation. It can happen that this will empty the column, in which case we can delink it. If the column isn't empty, queue it for further processing. */ presolve_delete_from_col(i,j,mcstrt,hincol,hrow,colels) ; if (hincol[j] == 0) { PRESOLVE_REMOVE_LINK(prob->clink_,j) ; } else { prob->addCol(j) ; } /* Update the solution, if it's present. The trick is maintaining the right number of basic variables. We've deleted a row, so we need to reduce the basis by one. There's a corner case that doesn't seem to be covered. What happens if both x(j) and s(i) are nonbasic? The number of basic variables will not be reduced. This is admittedly a pathological situation: It implies that there's an existing bound l(j) or u(j) exactly equal to the bound imposed by this constraint, so that x(j) can be nonbasic at bound and the constraint can be simultaneously tight. -- lh, 121115 -- */ if (rowstat) { int basisChoice = 0 ; int numberBasic = 0 ; double movement = 0 ; if (prob->columnIsBasic(j)) { numberBasic++ ; basisChoice = 2 ; // move to row to keep consistent } if (prob->rowIsBasic(i)) numberBasic++ ; PRESOLVEASSERT(numberBasic > 0) ; if (sol[j] <= clo[j]+ztolzb) { movement = clo[j]-sol[j] ; sol[j] = clo[j] ; prob->setColumnStatus(j,CoinPrePostsolveMatrix::atLowerBound) ; } else if (sol[j] >= cup[j]-ztolzb) { movement = cup[j]-sol[j] ; sol[j] = cup[j] ; prob->setColumnStatus(j,CoinPrePostsolveMatrix::atUpperBound) ; } else { basisChoice = 1 ; } if (numberBasic > 1 || basisChoice == 1) prob->setColumnStatus(j,CoinPrePostsolveMatrix::basic) ; else if (basisChoice==2) prob->setRowStatus(i,CoinPrePostsolveMatrix::basic) ; if (movement) { const CoinBigIndex &kcs = mcstrt[j] ; const CoinBigIndex kce = kcs+hincol[j] ; for (CoinBigIndex kcol = kcs ; kcol < kce ; kcol++) { int k = hrow[kcol] ; PRESOLVEASSERT(hinrow[k] > 0) ; acts[k] += movement*colels[kcol] ; } } } } /* Done with processing. Time to deal with the results. First add the postsolve actions for the singletons to the postsolve list. Then call remove_fixed_action to handle variables that were fixed during the loop. (We've already adjusted the solution, so make_fixed_action is not needed.) */ if (!infeas && nactions) { # if PRESOLVE_SUMMARY std::cout << "SINGLETON ROWS: " << nactions << std::endl ; # endif action *save_actions = new action[nactions] ; CoinMemcpyN(actions, nactions, save_actions) ; next = new slack_doubleton_action(nactions,save_actions,next) ; if (nfixed_cols) next = remove_fixed_action::presolve(prob,fixed_cols,nfixed_cols,next) ; } delete[] actions ; # if COIN_PRESOLVE_TUNING > 0 double thisTime ; if (prob->tuning_) double thisTime = CoinCpuTime() ; # endif # if PRESOLVE_CONSISTENCY > 0 || PRESOLVE_DEBUG > 0 presolve_consistent(prob) ; presolve_links_ok(prob) ; presolve_check_sol(prob) ; presolve_check_nbasic(prob) ; # endif # if PRESOLVE_DEBUG > 0 || COIN_PRESOLVE_TUNING > 0 int droppedRows = prob->countEmptyRows()-startEmptyRows ; int droppedColumns = prob->countEmptyCols()-startEmptyColumns ; std::cout << "Leaving slack_doubleton_action::presolve, " << droppedRows << " rows, " << droppedColumns << " columns dropped" ; #if COIN_PRESOLVE_TUNING > 0 std::cout << " in " << (thisTime-startTime) << "s, total " << (thisTime-prob->startTime_) ; # endif std::cout << "." << std::endl ; # endif return (next) ; } void slack_doubleton_action::postsolve(CoinPostsolveMatrix *prob) const { const action *const actions = actions_ ; const int nactions = nactions_ ; double *colels = prob->colels_ ; int *hrow = prob->hrow_ ; CoinBigIndex *mcstrt = prob->mcstrt_ ; int *hincol = prob->hincol_ ; int *link = prob->link_ ; double *clo = prob->clo_ ; double *cup = prob->cup_ ; double *sol = prob->sol_ ; double *rcosts = prob->rcosts_ ; unsigned char *colstat = prob->colstat_ ; double *rlo = prob->rlo_ ; double *rup = prob->rup_ ; double *acts = prob->acts_ ; double *rowduals = prob->rowduals_ ; # if PRESOLVE_DEBUG char *rdone = prob->rdone_ ; std::cout << "Entering slack_doubleton_action::postsolve, " << nactions << " constraints to process." << std::endl ; presolve_check_sol(prob,2,2,2) ; presolve_check_nbasic(prob) ; # endif CoinBigIndex &free_list = prob->free_list_ ; const double ztolzb = prob->ztolzb_ ; for (const action *f = &actions[nactions-1] ; actions <= f ; f--) { int irow = f->row ; double lo0 = f->clo ; double up0 = f->cup ; double coeff = f->coeff ; int jcol = f->col ; rlo[irow] = f->rlo ; rup[irow] = f->rup ; clo[jcol] = lo0 ; cup[jcol] = up0 ; acts[irow] = coeff*sol[jcol] ; /* Create the row and restore the single coefficient, linking the new coefficient at the start of the column. */ { CoinBigIndex k = free_list ; assert(k >= 0 && k < prob->bulk0_) ; free_list = link[free_list] ; hrow[k] = irow ; colels[k] = coeff ; link[k] = mcstrt[jcol] ; mcstrt[jcol] = k ; hincol[jcol]++ ; } /* Since we are adding a row, we have to set the row status and dual to satisfy complimentary slackness. We may also have to modify the column status and reduced cost if bounds have been relaxed. */ if (!colstat) { // ???? rowduals[irow] = 0.0 ; } else { if (prob->columnIsBasic(jcol)) { /* The variable is basic, hence the slack must be basic, hence the dual for the row is zero. Relaxing the bounds on a basic variable doesn't change anything. */ prob->setRowStatus(irow,CoinPrePostsolveMatrix::basic) ; rowduals[irow] = 0.0 ; } else if ((fabs(sol[jcol]-lo0) <= ztolzb && rcosts[jcol] >= 0) || (fabs(sol[jcol]-up0) <= ztolzb && rcosts[jcol] <= 0)) { /* The variable is nonbasic and the sign of the reduced cost is correct for the bound. Again, the slack will be basic and the dual zero. */ prob->setRowStatus(irow,CoinPrePostsolveMatrix::basic) ; rowduals[irow] = 0.0 ; } else if (!(fabs(sol[jcol]-lo0) <= ztolzb) && !(fabs(sol[jcol]-up0) <= ztolzb)) { /* The variable was not basic but transferring bounds back to the constraint has relaxed the column bounds. The variable will need to be made basic. The constraint must then be tight and the dual must be set so that the reduced cost of the variable becomes zero. */ prob->setColumnStatus(jcol,CoinPrePostsolveMatrix::basic) ; prob->setRowStatusUsingValue(irow) ; rowduals[irow] = rcosts[jcol]/coeff ; rcosts[jcol] = 0.0 ; } else { /* The variable is at bound, but the reduced cost is wrong. Again set the row dual to bring the reduced cost to zero. This implies that the constraint is tight and the slack will be nonbasic. */ prob->setColumnStatus(jcol,CoinPrePostsolveMatrix::basic) ; prob->setRowStatusUsingValue(irow) ; rowduals[irow] = rcosts[jcol]/coeff ; rcosts[jcol] = 0.0 ; } } # if PRESOLVE_DEBUG > 0 || PRESOLVE_CONSISTENCY > 0 rdone[irow] = SLACK_DOUBLETON ; # endif } # if PRESOLVE_CONSISTENCY > 0 || PRESOLVE_DEBUG > 0 presolve_check_threads(prob) ; presolve_check_sol(prob,2,2,2) ; presolve_check_nbasic(prob) ; # endif # if PRESOLVE_DEBUG > 0 std::cout << "Leaving slack_doubleton_action::postsolve." << std::endl ; # endif return ; } /* If we have a variable with one entry and no cost then we can transform the row from E to G etc. If there is a row objective region then we may be able to do this even with a cost. */ const CoinPresolveAction * slack_singleton_action::presolve(CoinPresolveMatrix *prob, const CoinPresolveAction *next, double * rowObjective) { double startTime = 0.0 ; int startEmptyRows=0 ; int startEmptyColumns = 0 ; if (prob->tuning_) { startTime = CoinCpuTime() ; startEmptyRows = prob->countEmptyRows() ; startEmptyColumns = prob->countEmptyCols() ; } double *colels = prob->colels_ ; int *hrow = prob->hrow_ ; CoinBigIndex *mcstrt = prob->mcstrt_ ; int *hincol = prob->hincol_ ; //int ncols = prob->ncols_ ; double *clo = prob->clo_ ; double *cup = prob->cup_ ; double *rowels = prob->rowels_ ; int *hcol = prob->hcol_ ; CoinBigIndex *mrstrt = prob->mrstrt_ ; int *hinrow = prob->hinrow_ ; int nrows = prob->nrows_ ; double *rlo = prob->rlo_ ; double *rup = prob->rup_ ; // Existence of unsigned char *rowstat = prob->rowstat_ ; double *acts = prob->acts_ ; double * sol = prob->sol_ ; const unsigned char *integerType = prob->integerType_ ; const double ztolzb = prob->ztolzb_ ; double *dcost = prob->cost_ ; //const double maxmin = prob->maxmin_ ; # if PRESOLVE_DEBUG std::cout << "Entering slack_singleton_action::presolve." << std::endl ; presolve_check_sol(prob) ; presolve_check_nbasic(prob) ; # endif int numberLook = prob->numberColsToDo_ ; int iLook ; int * look = prob->colsToDo_ ; // Make sure we allocate at least one action int maxActions = CoinMin(numberLook,nrows/10)+1 ; action * actions = new action[maxActions] ; int nactions = 0 ; int * fixed_cols = new int [numberLook] ; int nfixed_cols=0 ; int nWithCosts=0 ; double costOffset=0.0 ; for (iLook=0;iLookcolProhibited(iCol)) { double currentLower = rlo[iRow] ; double currentUpper = rup[iRow] ; if (!rowObjective) { if (dcost[iCol]) continue ; } else if ((dcost[iCol]&¤tLower!=currentUpper)||rowObjective[iRow]) { continue ; } double newLower=currentLower ; double newUpper=currentUpper ; if (coeff<0.0) { if (currentUpper>1.0e20||cup[iCol]>1.0e20) { newUpper=COIN_DBL_MAX ; } else { newUpper -= coeff*cup[iCol] ; if (newUpper>1.0e20) newUpper=COIN_DBL_MAX ; } if (currentLower<-1.0e20||clo[iCol]<-1.0e20) { newLower=-COIN_DBL_MAX ; } else { newLower -= coeff*clo[iCol] ; if (newLower<-1.0e20) newLower=-COIN_DBL_MAX ; } } else { if (currentUpper>1.0e20||clo[iCol]<-1.0e20) { newUpper=COIN_DBL_MAX ; } else { newUpper -= coeff*clo[iCol] ; if (newUpper>1.0e20) newUpper=COIN_DBL_MAX ; } if (currentLower<-1.0e20||cup[iCol]>1.0e20) { newLower=-COIN_DBL_MAX ; } else { newLower -= coeff*cup[iCol] ; if (newLower<-1.0e20) newLower=-COIN_DBL_MAX ; } } if (integerType&&integerType[iCol]) { // only possible if everything else integer if (newLower>-1.0e30) { if (newLower!=floor(newLower+0.5)) continue ; } if (newUpper<1.0e30) { if (newUpper!=floor(newUpper+0.5)) continue ; } bool allInt=true ; for (CoinBigIndex j=mrstrt[iRow] ; j=maxActions) { maxActions += CoinMin(numberLook-iLook,maxActions) ; action * temp = new action[maxActions] ; memcpy(temp,actions,nactions*sizeof(action)) ; // changed as 4.6 compiler bug! CoinMemcpyN(actions,nactions,temp) ; delete [] actions ; actions=temp ; } action *s = &actions[nactions] ; nactions++ ; s->col = iCol ; s->clo = clo[iCol] ; s->cup = cup[iCol] ; s->row = iRow ; s->rlo = rlo[iRow] ; s->rup = rup[iRow] ; s->coeff = coeff ; presolve_delete_from_row(iRow,iCol,mrstrt,hinrow,hcol,rowels) ; if (!hinrow[iRow]) PRESOLVE_REMOVE_LINK(prob->rlink_,iRow) ; // put row on stack of things to do next time prob->addRow(iRow) ; #ifdef PRINTCOST if (rowObjective&&dcost[iCol]) { printf("Singleton %d had coeff of %g in row %d - bounds %g %g - cost %g\n", iCol,coeff,iRow,clo[iCol],cup[iCol],dcost[iCol]) ; printf("Row bounds were %g %g now %g %g\n", rlo[iRow],rup[iRow],newLower,newUpper) ; } #endif // Row may be redundant but let someone else do that rlo[iRow]=newLower ; rup[iRow]=newUpper ; if (rowstat&&sol) { // update solution and basis if ((sol[iCol] < cup[iCol]-ztolzb&& sol[iCol] > clo[iCol]+ztolzb)||prob->columnIsBasic(iCol)) prob->setRowStatus(iRow,CoinPrePostsolveMatrix::basic) ; prob->setColumnStatusUsingValue(iCol) ; } // Force column to zero clo[iCol]=0.0 ; cup[iCol]=0.0 ; if (rowObjective&&dcost[iCol]) { rowObjective[iRow]=-dcost[iCol]/coeff ; nWithCosts++ ; // adjust offset costOffset += currentLower*rowObjective[iRow] ; prob->dobias_ -= currentLower*rowObjective[iRow] ; } if (sol) { double movement ; if (fabs(sol[iCol]-clo[iCol])clink_,iCol) ; //clo[iCol] = 0.0 ; //cup[iCol] = 0.0 ; fixed_cols[nfixed_cols++] = iCol ; //presolve_consistent(prob) ; } } } if (nactions) { # if PRESOLVE_SUMMARY printf("SINGLETON COLS: %d\n", nactions) ; # endif #ifdef COIN_DEVELOP printf("%d singletons, %d with costs - offset %g\n",nactions, nWithCosts, costOffset) ; #endif action *save_actions = new action[nactions] ; CoinMemcpyN(actions, nactions, save_actions) ; next = new slack_singleton_action(nactions, save_actions, next) ; if (nfixed_cols) next = make_fixed_action::presolve(prob, fixed_cols, nfixed_cols, true, // arbitrary next) ; } delete [] actions ; delete [] fixed_cols ; if (prob->tuning_) { double thisTime=CoinCpuTime() ; int droppedRows = prob->countEmptyRows() - startEmptyRows ; int droppedColumns = prob->countEmptyCols() - startEmptyColumns ; printf("CoinPresolveSingleton(3) - %d rows, %d columns dropped in time %g, total %g\n", droppedRows,droppedColumns,thisTime-startTime,thisTime-prob->startTime_) ; } # if PRESOLVE_DEBUG presolve_check_sol(prob) ; presolve_check_nbasic(prob) ; std::cout << "Leaving slack_singleton_action::presolve." << std::endl ; # endif return (next) ; } void slack_singleton_action::postsolve(CoinPostsolveMatrix *prob) const { const action *const actions = actions_ ; const int nactions = nactions_ ; double *colels = prob->colels_ ; int *hrow = prob->hrow_ ; CoinBigIndex *mcstrt = prob->mcstrt_ ; int *hincol = prob->hincol_ ; int *link = prob->link_ ; // int ncols = prob->ncols_ ; //double *rowels = prob->rowels_ ; //int *hcol = prob->hcol_ ; //CoinBigIndex *mrstrt = prob->mrstrt_ ; //int *hinrow = prob->hinrow_ ; double *clo = prob->clo_ ; double *cup = prob->cup_ ; double *rlo = prob->rlo_ ; double *rup = prob->rup_ ; double *sol = prob->sol_ ; double *rcosts = prob->rcosts_ ; double *acts = prob->acts_ ; double *rowduals = prob->rowduals_ ; double *dcost = prob->cost_ ; //const double maxmin = prob->maxmin_ ; unsigned char *colstat = prob->colstat_ ; // unsigned char *rowstat = prob->rowstat_ ; # if PRESOLVE_DEBUG char *rdone = prob->rdone_ ; std::cout << "Entering slack_singleton_action::postsolve." << std::endl ; presolve_check_sol(prob) ; presolve_check_nbasic(prob) ; # endif CoinBigIndex &free_list = prob->free_list_ ; const double ztolzb = prob->ztolzb_ ; #ifdef CHECK_ONE_ROW { double act=0.0 ; for (int i=0;incols_;i++) { double solV = sol[i] ; assert (solV>=clo[i]-ztolzb&&solV<=cup[i]+ztolzb) ; int j=mcstrt[i] ; for (int k=0;k=rlo[CHECK_ONE_ROW]-ztolzb&&act<=rup[CHECK_ONE_ROW]+ztolzb) ; printf("start %g %g %g %g\n",rlo[CHECK_ONE_ROW],act,acts[CHECK_ONE_ROW],rup[CHECK_ONE_ROW]) ; } #endif for (const action *f = &actions[nactions-1]; actions<=f; f--) { int iRow = f->row ; double lo0 = f->clo ; double up0 = f->cup ; double coeff = f->coeff ; int iCol = f->col ; assert (!hincol[iCol]) ; #ifdef CHECK_ONE_ROW if (iRow==CHECK_ONE_ROW) printf("Col %d coeff %g old bounds %g,%g new %g,%g - new rhs %g,%g - act %g\n", iCol,coeff,clo[iCol],cup[iCol],lo0,up0,f->rlo,f->rup,acts[CHECK_ONE_ROW]) ; #endif rlo[iRow] = f->rlo ; rup[iRow] = f->rup ; clo[iCol] = lo0 ; cup[iCol] = up0 ; double movement=0.0 ; // acts was without coefficient - adjust acts[iRow] += coeff*sol[iCol] ; if (acts[iRow]rup[iRow]+ztolzb) movement = rup[iRow]-acts[iRow] ; double cMove = movement/coeff ; sol[iCol] += cMove ; acts[iRow] += movement ; if (!dcost[iCol]) { // and to get column feasible cMove=0.0 ; if (sol[iCol]>cup[iCol]+ztolzb) cMove = cup[iCol]-sol[iCol] ; else if (sol[iCol]columnIsBasic(iCol)) numberBasic++ ; if (prob->rowIsBasic(iRow)) numberBasic++ ; #ifdef COIN_DEVELOP if (numberBasic>1) printf("odd in singleton\n") ; #endif if (sol[iCol]>clo[iCol]+ztolzb&&sol[iCol]setColumnStatus(iCol,CoinPrePostsolveMatrix::basic) ; prob->setRowStatusUsingValue(iRow) ; } else if (acts[iRow]>rlo[iRow]+ztolzb&&acts[iRow]setRowStatus(iRow,CoinPrePostsolveMatrix::basic) ; prob->setColumnStatusUsingValue(iCol) ; } else if (numberBasic) { prob->setRowStatus(iRow,CoinPrePostsolveMatrix::basic) ; prob->setColumnStatusUsingValue(iCol) ; } else { prob->setRowStatusUsingValue(iRow) ; prob->setColumnStatusUsingValue(iCol) ; } } # if PRESOLVE_DEBUG > 1 printf("SLKSING: %d = %g restored %d lb = %g ub = %g.\n", iCol,sol[iCol],prob->getColumnStatus(iCol),clo[iCol],cup[iCol]) ; # endif } else { // must have been equality row assert (rlo[iRow]==rup[iRow]) ; double cost = rcosts[iCol] ; // adjust for coefficient cost -= rowduals[iRow]*coeff ; bool basic=true ; if (fabs(sol[iCol]-cup[iCol])1.0e-6) basic=false ; //printf("Singleton %d had coeff of %g in row %d (dual %g) - bounds %g %g - cost %g, (dj %g)\n", // iCol,coeff,iRow,rowduals[iRow],clo[iCol],cup[iCol],dcost[iCol],rcosts[iCol]) ; //if (prob->columnIsBasic(iCol)) //printf("column basic! ") ; //if (prob->rowIsBasic(iRow)) //printf("row basic ") ; //printf("- make column basic %s\n",basic ? "yes" : "no") ; if (basic&&!prob->rowIsBasic(iRow)) { #ifdef PRINTCOST printf("Singleton %d had coeff of %g in row %d (dual %g) - bounds %g %g - cost %g, (dj %g - new %g)\n", iCol,coeff,iRow,rowduals[iRow],clo[iCol],cup[iCol],dcost[iCol],rcosts[iCol],cost) ; #endif #ifdef COIN_DEVELOP if (prob->columnIsBasic(iCol)) printf("column basic!\n") ; #endif basic=false ; } if (fabs(rowduals[iRow])>1.0e-6&&prob->rowIsBasic(iRow)) basic=true ; if (basic) { // Make basic have zero reduced cost rowduals[iRow] = rcosts[iCol] / coeff ; rcosts[iCol] = 0.0 ; } else { rcosts[iCol]=cost ; //rowduals[iRow]=0.0 ; } if (colstat) { if (basic) { if (!prob->rowIsBasic(iRow)) { #if 0 // find column in row int jCol=-1 ; //for (CoinBigIndex j=mrstrt[iRow];jncols0_;k++) { CoinBigIndex j=mcstrt[k] ; for (int i=0;isetColumnStatus(iCol,CoinPrePostsolveMatrix::basic) ; } prob->setRowStatusUsingValue(iRow) ; } else { //prob->setRowStatus(iRow,CoinPrePostsolveMatrix::basic) ; prob->setColumnStatusUsingValue(iCol) ; } } } #if 0 int nb=0 ; int kk ; for (kk=0;kknrows_;kk++) if (prob->rowIsBasic(kk)) nb++ ; for (kk=0;kkncols_;kk++) if (prob->columnIsBasic(kk)) nb++ ; assert (nb==prob->nrows_) ; #endif // add new element { CoinBigIndex k = free_list ; assert(k >= 0 && k < prob->bulk0_) ; free_list = link[free_list] ; hrow[k] = iRow ; colels[k] = coeff ; link[k] = mcstrt[iCol] ; mcstrt[iCol] = k ; } hincol[iCol]++; // right? #ifdef CHECK_ONE_ROW { double act=0.0 ; for (int i=0;incols_;i++) { double solV = sol[i] ; assert (solV>=clo[i]-ztolzb&&solV<=cup[i]+ztolzb) ; int j=mcstrt[i] ; for (int k=0;k=rlo[CHECK_ONE_ROW]-ztolzb&&act<=rup[CHECK_ONE_ROW]+ztolzb) ; printf("rhs now %g %g %g %g\n",rlo[CHECK_ONE_ROW],act,acts[CHECK_ONE_ROW],rup[CHECK_ONE_ROW]) ; } #endif # if PRESOLVE_DEBUG rdone[iRow] = SLACK_SINGLETON ; # endif } # if PRESOLVE_DEBUG presolve_check_sol(prob) ; presolve_check_nbasic(prob) ; std::cout << "Leaving slack_singleton_action::postsolve." << std::endl ; # endif return ; }