// $Id: CglTwomir.hpp 1119 2013-04-06 20:24:18Z stefan $ // 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). #ifndef CglTwomir_H #define CglTwomir_H #include #include "CglCutGenerator.hpp" #include "CoinFactorization.hpp" typedef struct { int nz; /* current length of arrays index[] and coeff[] */ int max_nz; /* max length of arrays index[] and coeff[] */ double *coeff; /* coefficient of each variable in the constraint */ int *index; /* index of the variable (value in 0 ... nrow+ncol) */ double rhs; /* rhs of the constraint */ char sense; /* ?? is it necessary */ } DGG_constraint_t; typedef struct{ int n; DGG_constraint_t **c; int *ctype; double *alpha; } DGG_list_t; /******************** BASIS INFORMATION ADTs **********************************/ typedef struct{ int q_min; int q_max; int t_min; int t_max; int a_max; int max_elements; } cutParams; typedef struct { double gomory_threshold; /* factional variable must be this away from int */ int ncol, /* number of columns in LP */ nrow, /* number of constaints in LP */ ninteger; /* number of integer variables in LP */ int nbasic_col, /* number of basic columns in the LP */ nbasic_row; /* number of basic rows in the LP */ /* the following arrays are all of size (ncol+nrow) */ int *info; /* description of each variable (see below) */ double *lb; /* specifies the lower bound (if any) of each variable */ double *ub; /* specifies the upper bound (if any) of each variable */ double *x; /* current solution */ double *rc; /* current reduced cost */ double *opt_x; cutParams cparams; } DGG_data_t; /* the following macros allow us to decode the info of the DGG_data type. The encoding is as follows, bit 1 : if the variable is basic or not (non-basic). bit 2 : if the variable is integer or or not (rational). bit 3 : if the variable is structural or not (artifical). bit 4 : if the variable is non-basic and at its upper bound (else if non-basic at lower bound). */ #define DGG_isBasic(data,idx) ((data->info[idx])&1) #define DGG_isInteger(data,idx) ((data->info[idx] >> 1)&1) #define DGG_isStructural(data,idx) ((data->info[idx] >> 2)&1) #define DGG_isEqualityConstraint(data,idx) ((data->info[idx] >> 3)&1) #define DGG_isNonBasicAtUB(data,idx) ((data->info[idx] >> 4)&1) #define DGG_isNonBasicAtLB(data,idx) ((data->info[idx] >> 5)&1) #define DGG_isConstraintBoundedAbove(data,idx) ((data->info[idx] >> 6)&1) #define DGG_isConstraintBoundedBelow(data,idx) ((data->info[idx] >> 7)&1) #define DGG_setIsBasic(data,idx) ((data->info[idx]) |= 1) #define DGG_setIsInteger(data,idx) ((data->info[idx]) |= (1<<1)) #define DGG_setIsStructural(data,idx) ((data->info[idx]) |= (1<<2)) #define DGG_setEqualityConstraint(data,idx) ((data->info[idx]) |= (1<<3)) #define DGG_setIsNonBasicAtUB(data,idx) ((data->info[idx]) |= (1<<4)) #define DGG_setIsNonBasicAtLB(data,idx) ((data->info[idx]) |= (1<<5)) #define DGG_setIsConstraintBoundedAbove(data,idx) ((data->info[idx]) |= (1<<6)) #define DGG_setIsConstraintBoundedBelow(data,idx) ((data->info[idx]) |= (1<<7)) class CoinWarmStartBasis; /** Twostep MIR Cut Generator Class */ class CglTwomir : public CglCutGenerator { friend void CglTwomirUnitTest(const OsiSolverInterface * siP, const std::string mpdDir ); public: /// Problem name std::string probname_; /**@name Generate Cuts */ //@{ /** Generate Two step MIR cuts either from the tableau rows or from the formulation rows */ virtual void generateCuts( const OsiSolverInterface & si, OsiCuts & cs, const CglTreeInfo info = CglTreeInfo()); /// Return true if needs optimal basis to do cuts (will return true) virtual bool needsOptimalBasis() const; /**@name Change criterion on which scalings to use (default = 1,1,1,1) */ //@{ /// Set void setMirScale (int tmin, int tmax) {t_min_ = tmin; t_max_ = tmax;} void setTwomirScale (int qmin, int qmax) {q_min_ = qmin; q_max_ = qmax;} void setAMax (int a) {a_max_ = a;} void setMaxElements (int n) {max_elements_ = n;} void setMaxElementsRoot (int n) {max_elements_root_ = n;} void setCutTypes (bool mir, bool twomir, bool tab, bool form) { do_mir_ = mir; do_2mir_ = twomir; do_tab_ = tab; do_form_ = form;} void setFormulationRows (int n) {form_nrows_ = n;} /// Get int getTmin() const {return t_min_;} int getTmax() const {return t_max_;} int getQmin() const {return q_min_;} int getQmax() const {return q_max_;} int getAmax() const {return a_max_;} int getMaxElements() const {return max_elements_;} int getMaxElementsRoot() const {return max_elements_root_;} int getIfMir() const { return do_mir_;} int getIfTwomir() const { return do_2mir_;} int getIfTableau() const { return do_tab_;} int getIfFormulation() const { return do_form_;} //@} /**@name Change criterion on which variables to look at. All ones more than "away" away from integrality will be investigated (default 0.05) */ //@{ /// Set away void setAway(double value); /// Get away double getAway() const; /// Set away at root void setAwayAtRoot(double value); /// Get away at root double getAwayAtRoot() const; /// Return maximum length of cut in tree virtual int maximumLengthOfCutInTree() const { return max_elements_;} //@} /**@name Change way TwoMir works */ //@{ /// Pass in a copy of original solver (clone it) void passInOriginalSolver(OsiSolverInterface * solver); /// Returns original solver inline OsiSolverInterface * originalSolver() const { return originalSolver_;} /// Set type - 0 normal, 1 add original matrix one, 2 replace inline void setTwomirType(int type) { twomirType_=type;} /// Return type inline int twomirType() const { return twomirType_;} //@} /**@name Constructors and destructors */ //@{ /// Default constructor CglTwomir (); /// Copy constructor CglTwomir (const CglTwomir &); /// Clone virtual CglCutGenerator * clone() const; /// Assignment operator CglTwomir & operator=(const CglTwomir& rhs); /// Destructor virtual ~CglTwomir (); /// Create C++ lines to get to current state virtual std::string generateCpp( FILE * fp); /// This can be used to refresh any inforamtion virtual void refreshSolver(OsiSolverInterface * solver); //@} private: // Private member data /**@name Private member data */ //@{ /// Threadsafe random number generator CoinThreadRandom randomNumberGenerator_; /// Original solver OsiSolverInterface * originalSolver_; /// Only investigate if more than this away from integrality double away_; /// Only investigate if more than this away from integrality (at root) double awayAtRoot_; /// Type - 0 normal, 1 add original matrix one, 2 replace int twomirType_; bool do_mir_; bool do_2mir_; bool do_tab_; bool do_form_; int t_min_; /// t_min - first value of t to use for tMIR inequalities int t_max_; /// t_max - last value of t to use for tMIR inequalities int q_min_; /// q_min - first value of t to use for 2-Step tMIR inequalities int q_max_; /// q_max - last value of t to use for 2-Step tMIR inequalities int a_max_; /// a_max - maximum value of bhat/alpha int max_elements_; /// Maximum number of elements in cut int max_elements_root_; /// Maximum number of elements in cut at root int form_nrows_; //number of rows on which formulation cuts will be generated //@} }; //############################################################################# /* #include #include #include #include #include #include #include */ /******************** DEBUG DEFINITIONS ***************************************/ #define DGG_DEBUG_DGG 1 #define DGG_TRACE_ERRORS 0 #define DGG_DISPLAY 0 #define DGG_AUTO_CHECK_CUT_OFF_OPTIMAL 1 /******************** CONFIGURATION DEFAULTS **********************************/ #define DGG_DEFAULT_METHOD 2 #define DGG_DEFAULT_TMIN 1 #define DGG_DEFAULT_TMAX 1 #define DGG_DEFAULT_TAUMIN 2 #define DGG_DEFAULT_TAUMAX 6 #define DGG_DEFAULT_MAX_CUTS 500 #define DGG_DEFAULT_IMPROVEMENT_THRESH 0.001 #define DGG_DEFAULT_NBELOW_THRESH INT_MAX #define DGG_DEFAULT_NROOT_ROUNDS 2 #define DGG_DEFAULT_NEGATIVE_SCALED_TWOSTEPS 0 #define DGG_DEFAULT_ALPHA_RULE 0 #define DGG_DEFAULT_CUT_INC 250 #define DGG_DEFAULT_CUT_FORM 0 #define DGG_DEFAULT_NICEFY 0 #define DGG_DEFAULT_ONLY_DELAYED 0 #define DGG_DEFAULT_DELAYED_FREQ 9999999 #define DGG_DEFAULT_LPROWS_FREQ 9999999 #define DGG_DEFAULT_WHICH_FORMULATION_CUTS 2 /******************** SOLVER CONFIGURATION DEFINITIONS ************************/ #define DGG_OSI 0 #define DGG_CPX 1 #define DGG_QSO 2 /* determines the solver to be used */ #define DGG_SOLVER DGG_OSI /* adds checking routines to make sure solver works as expected */ #define DGG_DEBUG_SOLVER 0 /* turn off screen output from solver */ #define DGG_SOLVER_SCREEN_FLAG 0 /******************** CUT DEFINITIONS *****************************************/ /* internal names for cut types */ #define DGG_TMIR_CUT 1 #define DGG_2STEP_CUT 2 /* internal names for alpha-selection rules */ #define DGG_ALPHA_MIN_SUM 0 #define DGG_ALPHA_RANDOM_01 1 #define DGG_ALPHA_RANDOM_COEFF 2 #define DGG_ALPHA_ALL 3 #define DGG_ALPHA_MAX_STEEP 5 /******************** PRECISION & NUMERICAL ISSUES DEFINITIONS ****************/ /* how steep a cut must be before adding it to the lp */ #define DGG_MIN_STEEPNESS 1.0e-4 #define DGG_MAX_L2NORM 1.0e7 /* 0 = min steepness, 1 = max norm */ #define DGG_NORM_CRITERIA 1 /* internal representation of +infinity */ #define UB_MAX DBL_MAX /* used to define how fractional a basic-integer variable must be before choosing to use it to generate a TMIR cut on. OSI's default is 1.0e-7 */ #define DGG_GOMORY_THRESH 0.005 #define DGG_RHS_THRESH 0.005 /* used for comparing variables to their upper bounds. OSI's default is 1.0e-7. We set it to 1.0e6 because e-7 seems too sensitive. In fact, with e-7 the problem dsbmip.mps complains. */ #define DGG_BOUND_THRESH 1.0e-6 /* used for comparing the lhs (activity) value of a tableau row with the rhs. This is only used for debugging purposes. */ #define DGG_EQUALITY_THRESH 1.0e-5 /* used for comparing a variable's lower bound to 0.0 and determining if we need to shift the variable */ #define DGG_SHIFT_THRESH 1.0e-6 /* used for determing how far from an integer is still an integer. This value is used for comparing coefficients to integers. OSI's default is 1.0e-10. */ #define DGG_INTEGRALITY_THRESH 1.0e-10 /* the min value that a coeff can have in the tableau row before being set to zero. */ #define CBC_CHECK_CUT #ifndef CBC_CHECK_CUT #define DGG_MIN_TABLEAU_COEFFICIENT 1.0e-8 #else #define DGG_MIN_TABLEAU_COEFFICIENT 1.0e-12 #endif /* smallest value rho is allowed to have for a simple 2-step MIR (ie: not an extended two-step MIR) */ #define DGG_MIN_RHO 1.0e-7 #define DGG_MIN_ALPHA 1.0e-7 /* when a slack is null: used to check if a cut is satisfied or not. */ #define DGG_NULL_SLACK 1.0e-5 /* nicefy constants */ #define DGG_NICEFY_MIN_ABSVALUE 1.0e-13 #define DGG_NICEFY_MIN_FIX 1.0e-7 #define DGG_NICEFY_MAX_PADDING 1.0e-6 #define DGG_NICEFY_MAX_RATIO 1.0e9 /******************** ERROR-CATCHING MACROS ***********************************/ #if DGG_TRACE_ERRORS > 0 #define __DGG_PRINT_LOC__(F) fprintf(((F==0)?stdout:F), " in %s (%s:%d)\n", __func__, __FILE__, __LINE__) #define DGG_THROW(A,REST...) {\ fprintf(stdout, ##REST); \ __DGG_PRINT_LOC__(stdout); \ return (A);} #define DGG_IF_EXIT(A,B,REST...) {\ if(A) {\ fprintf(stdout, ##REST); \ __DGG_PRINT_LOC__(stdout); \ exit(B);}} #define DGG_CHECKRVAL(A,B) {\ if(A) {\ __DGG_PRINT_LOC__(stdout); \ return B; } } #define DGG_CHECKRVAL1(A,B) {\ if(A) {\ __DGG_PRINT_LOC__(stdout); \ rval = B; goto CLEANUP; } } #define DGG_WARNING(A, REST...) {\ if(A) {\ fprintf(stdout, ##REST); \ __DGG_PRINT_LOC__(stdout); \ }} #define DGG_TEST(A,B,REST...) {\ if(A) DGG_THROW(B,##REST) } #define DGG_TEST2(A,B,C,REST) {DGG_TEST(A,B,C,REST) } #define DGG_TEST3(A,B,C,D,REST) {DGG_TEST(A,B,C,D,REST) } #else #define DGG_IF_EXIT(A,B,REST) {if(A) {fprintf(stdout, REST);exit(B);}} #define DGG_THROW(A,B) return(A) #define DGG_CHECKRVAL(A,B) { if(A) return(B); } #define DGG_CHECKRVAL1(A,B){ if(A) { rval = B; goto CLEANUP; } } #define DGG_TEST(A,B,REST) { if(A) return(B);} #define DGG_TEST2(A,B,REST,C) { DGG_TEST(A,B,REST) } #define DGG_TEST3(A,B,REST,C,D) { DGG_TEST(A,B,REST) } #endif /******************** SIMPLE MACROS AND FUNCTIONS *****************************/ #define DGG_MIN(a,b) ( (ab)?a:b ) #define KREM(vht,alpha,tau) (DGG_MIN( ceil(vht / alpha), tau ) - 1) #define LMIN(vht, d, bht) (DGG_MIN( floor(d*bht/bht), d)) #define ABOV(v) (v - floor(v)) #define QINT(vht,bht,tau) ( (int)floor( (vht*(tau-1))/bht ) ) #define V2I(bht,tau,i) ( ((i+1)*bht / tau) ) int DGG_is_even(double vht, double bht, int tau, int q); double frac_part(double value); int DGG_is_a_multiple_of_b(double a, double b); /* free function for DGG_data_t. Frees internal arrays and data structure */ int DGG_freeData( DGG_data_t *data ); /******************** CONSTRAINT ADTs *****************************************/ DGG_constraint_t* DGG_newConstraint(int max_arrays); void DGG_freeConstraint(DGG_constraint_t *c); DGG_constraint_t *DGG_copyConstraint(DGG_constraint_t *c); void DGG_scaleConstraint(DGG_constraint_t *c, int t); /******************** CONFIGURATION *******************************************/ void DGG_list_init (DGG_list_t *l); int DGG_list_addcut (DGG_list_t *l, DGG_constraint_t *cut, int ctype, double alpha); void DGG_list_delcut (DGG_list_t *l, int i); void DGG_list_free(DGG_list_t *l); /******************* SOLVER SPECIFIC METHODS **********************************/ DGG_data_t *DGG_getData(const void *solver_ptr); /******************* CONSTRAINT MANIPULATION **********************************/ /* DGG_transformConstraint: manipulates a constraint in the following way: packs everything in output 1 - variables at their upper bounds are substituted for their complements. This is done by adjusting the coefficients and the right hand side (simple substitution). 2 - variables with non-zero lower bounds are shifted. */ int DGG_transformConstraint( DGG_data_t *data, double **x_out, double **rc_out, char **isint_out, DGG_constraint_t *constraint ); /* DGG_unTransformConstraint : 1 - Undoes step (1) of DGG_transformConstraint 2 - Undoes step (2) of DGG_transformConstraint */ int DGG_unTransformConstraint( DGG_data_t *data, DGG_constraint_t *constraint ); /* substitutes each slack variable by the structural variables which define it. This function, hence, changes the constraint 'cut'. */ int DGG_substituteSlacks( const void *solver_ptr, DGG_data_t *data, DGG_constraint_t *cut ); int DGG_nicefyConstraint( const void *solver_ptr, DGG_data_t *data, DGG_constraint_t *cut); /******************* CUT GENERATION *******************************************/ int DGG_getFormulaConstraint( int row_idx, const void *solver_ptr, DGG_data_t *data, DGG_constraint_t* row ); int DGG_getTableauConstraint( int index, const void *solver_ptr, DGG_data_t *data, DGG_constraint_t* tabrow, const int * colIsBasic, const int * rowIsBasic, CoinFactorization & factorization, int mode ); DGG_constraint_t* DGG_getSlackExpression(const void *solver_ptr, DGG_data_t* data, int row_index); int DGG_generateTabRowCuts( DGG_list_t *list, DGG_data_t *data, const void *solver_ptr ); int DGG_generateFormulationCuts( DGG_list_t *list, DGG_data_t *data, const void *solver_ptr, int nrows, CoinThreadRandom & generator); int DGG_generateFormulationCutsFromBase( DGG_constraint_t *base, double slack, DGG_list_t *list, DGG_data_t *data, const void *solver_ptr, CoinThreadRandom & generator); int DGG_generateCutsFromBase( DGG_constraint_t *base, DGG_list_t *list, DGG_data_t *data, const void *solver_ptr ); int DGG_buildMir( char *isint, DGG_constraint_t *base, DGG_constraint_t **cut_out ); int DGG_build2step( double alpha, char *isint, DGG_constraint_t *base, DGG_constraint_t **cut_out ); int DGG_addMirToList ( DGG_constraint_t *base, char *isint, double *x, DGG_list_t *list, DGG_data_t *data, DGG_constraint_t *orig_base ); int DGG_add2stepToList ( DGG_constraint_t *base, char *isint, double *x, double *rc, DGG_list_t *list, DGG_data_t *data, DGG_constraint_t *orig_base ); /******************* CUT INFORMATION ******************************************/ double DGG_cutLHS(DGG_constraint_t *c, double *x); int DGG_isCutDesirable(DGG_constraint_t *c, DGG_data_t *d); /******************* TEST / DEBUGGING ROUTINES ********************************/ int DGG_isConstraintViolated(DGG_data_t *d, DGG_constraint_t *c); int DGG_isBaseTrivial(DGG_data_t *d, DGG_constraint_t* c); int DGG_is2stepValid(double alpha, double bht); int DGG_cutsOffPoint(double *x, DGG_constraint_t *cut); //############################################################################# /** A function that tests the methods in the CglTwomir class. The only reason for it not to be a member method is that this way it doesn't have to be compiled into the library. And that's a gain, because the library should be compiled with optimization on, but this method should be compiled with debugging. */ void CglTwomirUnitTest(const OsiSolverInterface * siP, const std::string mpdDir); #endif