COIN-OR::LEMON - Graph Library

source: lemon-0.x/src/work/marci/lp/lp_solver_wrapper_2.h @ 1074:4a24a46407db

Last change on this file since 1074:4a24a46407db was 1048:38a49245a701, checked in by marci, 20 years ago

minor changes for various number types

File size: 16.4 KB
Line 
1// -*- c++ -*-
2#ifndef LEMON_LP_SOLVER_WRAPPER_H
3#define LEMON_LP_SOLVER_WRAPPER_H
4
5///\ingroup misc
6///\file
7///\brief Dijkstra algorithm.
8
9// #include <stdio.h>
10#include <stdlib.h>
11// #include <stdio>
12//#include <stdlib>
13extern "C" {
14#include "glpk.h"
15}
16
17#include <iostream>
18#include <vector>
19#include <string>
20#include <list>
21#include <memory>
22#include <utility>
23
24//#include <sage_graph.h>
25//#include <lemon/list_graph.h>
26//#include <lemon/graph_wrapper.h>
27#include <lemon/invalid.h>
28//#include <bfs_dfs.h>
29//#include <stp.h>
30//#include <lemon/max_flow.h>
31//#include <augmenting_flow.h>
32//#include <iter_map.h>
33
34using std::cout;
35using std::cin;
36using std::endl;
37
38namespace lemon {
39
40 
41  /// \addtogroup misc
42  /// @{
43
44  /// \brief A partitioned vector with iterable classes.
45  ///
46  /// This class implements a container in which the data is stored in an
47  /// stl vector, the range is partitioned into sets and each set is
48  /// doubly linked in a list.
49  /// That is, each class is iterable by lemon iterators, and any member of
50  /// the vector can bo moved to an other class.
51  template <typename T>
52  class IterablePartition {
53  protected:
54    struct Node {
55      T data;
56      int prev; //invalid az -1
57      int next;
58    };
59    std::vector<Node> nodes;
60    struct Tip {
61      int first;
62      int last;
63    };
64    std::vector<Tip> tips;
65  public:
66    /// The classes are indexed by integers from \c 0 to \c classNum()-1.
67    int classNum() const { return tips.size(); }
68    /// This lemon style iterator iterates through a class.
69    class ClassIt;
70    /// Constructor. The number of classes is to be given which is fixed
71    /// over the life of the container.
72    /// The partition classes are indexed from 0 to class_num-1.
73    IterablePartition(int class_num) {
74      for (int i=0; i<class_num; ++i) {
75        Tip t;
76        t.first=t.last=-1;
77        tips.push_back(t);
78      }
79    }
80  protected:
81    void befuz(ClassIt it, int class_id) {
82      if (tips[class_id].first==-1) {
83        if (tips[class_id].last==-1) {
84          nodes[it.i].prev=nodes[it.i].next=-1;
85          tips[class_id].first=tips[class_id].last=it.i;
86        }
87      } else {
88        nodes[it.i].prev=tips[class_id].last;
89        nodes[it.i].next=-1;
90        nodes[tips[class_id].last].next=it.i;
91        tips[class_id].last=it.i;
92      }
93    }
94    void kifuz(ClassIt it, int class_id) {
95      if (tips[class_id].first==it.i) {
96        if (tips[class_id].last==it.i) {
97          tips[class_id].first=tips[class_id].last=-1;
98        } else {
99          tips[class_id].first=nodes[it.i].next;
100          nodes[nodes[it.i].next].prev=-1;
101        }
102      } else {
103        if (tips[class_id].last==it.i) {
104          tips[class_id].last=nodes[it.i].prev;
105          nodes[nodes[it.i].prev].next=-1;
106        } else {
107          nodes[nodes[it.i].next].prev=nodes[it.i].prev;
108          nodes[nodes[it.i].prev].next=nodes[it.i].next;
109        }
110      }
111    }
112  public:
113    /// A new element with data \c t is pushed into the vector and into class
114    /// \c class_id.
115    ClassIt push_back(const T& t, int class_id) {
116      Node n;
117      n.data=t;
118      nodes.push_back(n);
119      int i=nodes.size()-1;
120      befuz(i, class_id);
121      return i;
122    }
123    /// A member is moved to an other class.
124    void set(ClassIt it, int old_class_id, int new_class_id) {
125      kifuz(it.i, old_class_id);
126      befuz(it.i, new_class_id);
127    }
128    /// Returns the data pointed by \c it.
129    T& operator[](ClassIt it) { return nodes[it.i].data; }
130    /// Returns the data pointed by \c it.
131    const T& operator[](ClassIt it) const { return nodes[it.i].data; }
132    ///.
133    class ClassIt {
134      friend class IterablePartition;
135    protected:
136      int i;
137    public:
138      /// Default constructor.
139      ClassIt() { }
140      /// This constructor constructs an iterator which points
141      /// to the member of th container indexed by the integer _i.
142      ClassIt(const int& _i) : i(_i) { }
143      /// Invalid constructor.
144      ClassIt(const Invalid&) : i(-1) { }
145    };
146    /// First member of class \c class_id.
147    ClassIt& first(ClassIt& it, int class_id) const {
148      it.i=tips[class_id].first;
149      return it;
150    }
151    /// Next member.
152    ClassIt& next(ClassIt& it) const {
153      it.i=nodes[it.i].next;
154      return it;
155    }
156    /// True iff the iterator is valid.
157    bool valid(const ClassIt& it) const { return it.i!=-1; }
158  };
159
160  /*! \e
161   */
162  template <typename _Value>
163  class LPSolverBase {
164  public:
165    /// \e
166    typedef _Value Value;
167    /// \e
168    typedef IterablePartition<int>::ClassIt RowIt;
169    /// \e
170    typedef IterablePartition<int>::ClassIt ColIt;
171  protected:
172    /// \e
173    IterablePartition<int> row_iter_map;
174    /// \e
175    IterablePartition<int> col_iter_map;
176    /// \e
177    const int VALID_ID;
178    /// \e
179    const int INVALID_ID;
180  public:
181    /// \e
182    LPSolverBase() : row_iter_map(2),
183                     col_iter_map(2),
184                     VALID_ID(0), INVALID_ID(1) { }
185    /// \e
186    virtual ~LPSolverBase() { }
187    /// \e
188    virtual void setMinimize() = 0;
189    /// \e
190    virtual void setMaximize() = 0;
191    /// \e
192    virtual RowIt addRow() = 0;
193    /// \e
194    virtual ColIt addCol() = 0;
195    /// temporally, glpk style indexing
196    virtual void setRowCoeffs(RowIt row_it, int num,
197                              int* indices, _Value* doubles) = 0;
198    //pair<RowIt, _Value>-bol kell megadni egy std range-et
199    /// \e
200    template <typename Begin, typename End>
201    void setRowCoeffs(RowIt row_it, Begin begin, End end) {
202      int mem_length=1+colNum();
203      int* indices = new int[mem_length];
204      _Value* doubles = new _Value[mem_length];
205      int length=0;
206      for ( ; begin!=end; ++begin) {
207        ++length;
208        indices[length]=col_iter_map[begin->first];
209        doubles[length]=begin->second;
210      }
211      setRowCoeffs(row_it, length, indices, doubles);
212      delete [] indices;
213      delete [] doubles;
214    }
215    /// temporally, glpk style indexing
216    virtual void setColCoeffs(ColIt col_it, int num,
217                              int* indices, _Value* doubles) = 0;
218    //pair<ColIt, _Value>-bol kell megadni egy std range-et
219    /// \e
220    template <typename Begin, typename End>
221    void setColCoeffs(ColIt col_it, Begin begin, End end) {
222      int mem_length=1+rowNum();
223      int* indices = new int[mem_length];
224      _Value* doubles = new _Value[mem_length];
225      int length=0;
226      for ( ; begin!=end; ++begin) {
227        ++length;
228        indices[length]=row_iter_map[begin->first];
229        doubles[length]=begin->second;
230      }
231      setColCoeffs(col_it, length, indices, doubles);
232      delete [] indices;
233      delete [] doubles;
234    }
235    /// \e
236    virtual void eraseCol(const ColIt& col_it) = 0;
237    /// \e
238    virtual void eraseRow(const RowIt& row_it) = 0;
239    /// \e
240    virtual void setColBounds(const ColIt& col_it, int bound_type,
241                              _Value lo, _Value up) =0;
242    /// \e
243    virtual _Value getObjCoef(const ColIt& col_it) = 0;
244    /// \e
245    virtual void setRowBounds(const RowIt& row_it, int bound_type,
246                              _Value lo, _Value up) = 0;
247    /// \e
248    virtual void setObjCoef(const ColIt& col_it, _Value obj_coef) = 0;
249    /// \e
250    virtual void solveSimplex() = 0;
251    /// \e
252    virtual void solvePrimalSimplex() = 0;
253    /// \e
254    virtual void solveDualSimplex() = 0;
255    /// \e
256    virtual _Value getPrimal(const ColIt& col_it) = 0;
257    /// \e
258    virtual _Value getObjVal() = 0;
259    /// \e
260    virtual int rowNum() const = 0;
261    /// \e
262    virtual int colNum() const = 0;
263    /// \e
264    virtual int warmUp() = 0;
265    /// \e
266    virtual void printWarmUpStatus(int i) = 0;
267    /// \e
268    virtual int getPrimalStatus() = 0;
269    /// \e
270    virtual void printPrimalStatus(int i) = 0;
271    /// \e
272    virtual int getDualStatus() = 0;
273    /// \e
274    virtual void printDualStatus(int i) = 0;
275    /// Returns the status of the slack variable assigned to row \c row_it.
276    virtual int getRowStat(const RowIt& row_it) = 0;
277    /// \e
278    virtual void printRowStatus(int i) = 0;
279    /// Returns the status of the variable assigned to column \c col_it.
280    virtual int getColStat(const ColIt& col_it) = 0;
281    /// \e
282    virtual void printColStatus(int i) = 0;
283  };
284 
285
286  /// \brief Wrappers for LP solvers
287  ///
288  /// This class implements a lemon wrapper for glpk.
289  /// Later other LP-solvers will be wrapped into lemon.
290  /// The aim of this class is to give a general surface to different
291  /// solvers, i.e. it makes possible to write algorithms using LP's,
292  /// in which the solver can be changed to an other one easily.
293  class LPSolverWrapper : public LPSolverBase<double> {
294  public:
295    typedef LPSolverBase<double> Parent;
296
297    //   class Row {
298    //   protected:
299    //     int i;
300    //   public:
301    //     Row() { }
302    //     Row(const Invalid&) : i(0) { }
303    //     Row(const int& _i) : i(_i) { }
304    //     operator int() const { return i; }
305    //   };
306    //   class RowIt : public Row {
307    //   public:
308    //     RowIt(const Row& row) : Row(row) { }
309    //   };
310
311    //   class Col {
312    //   protected:
313    //     int i;
314    //   public:
315    //     Col() { }
316    //     Col(const Invalid&) : i(0) { }
317    //     Col(const int& _i) : i(_i) { }
318    //     operator int() const { return i; }
319    //   };
320    //   class ColIt : public Col {
321    //     ColIt(const Col& col) : Col(col) { }
322    //   };
323
324  public:
325    /// \e
326    LPX* lp;
327
328  public:
329    /// \e
330    LPSolverWrapper() : Parent(),
331                        lp(lpx_create_prob()) {
332      lpx_set_int_parm(lp, LPX_K_DUAL, 1);
333    }
334    /// \e
335    ~LPSolverWrapper() {
336      lpx_delete_prob(lp);
337    }
338    /// \e
339    void setMinimize() {
340      lpx_set_obj_dir(lp, LPX_MIN);
341    }
342    /// \e
343    void setMaximize() {
344      lpx_set_obj_dir(lp, LPX_MAX);
345    }
346    /// \e
347    ColIt addCol() {
348      int i=lpx_add_cols(lp, 1); 
349      ColIt col_it;
350      col_iter_map.first(col_it, INVALID_ID);
351      if (col_iter_map.valid(col_it)) { //van hasznalhato hely
352        col_iter_map.set(col_it, INVALID_ID, VALID_ID);
353        col_iter_map[col_it]=i;
354        //col_id_to_lp_col_id[col_iter_map[col_it]]=i;
355      } else { //a cucc vegere kell inzertalni mert nincs szabad hely
356        //col_id_to_lp_col_id.push_back(i);
357        //int j=col_id_to_lp_col_id.size()-1;
358        col_it=col_iter_map.push_back(i, VALID_ID);
359      }
360      //    edge_index_map.set(e, i);
361      //    lpx_set_col_bnds(lp, i, LPX_DB, 0.0, 1.0);
362      //    lpx_set_obj_coef(lp, i, cost[e]);   
363      return col_it;
364    }
365    /// \e
366    RowIt addRow() {
367      int i=lpx_add_rows(lp, 1); 
368      RowIt row_it;
369      row_iter_map.first(row_it, INVALID_ID);
370      if (row_iter_map.valid(row_it)) { //van hasznalhato hely
371        row_iter_map.set(row_it, INVALID_ID, VALID_ID);
372        row_iter_map[row_it]=i;
373      } else { //a cucc vegere kell inzertalni mert nincs szabad hely
374        row_it=row_iter_map.push_back(i, VALID_ID);
375      }
376      return row_it;
377    }
378    using Parent::setRowCoeffs;
379    void setRowCoeffs(RowIt row_it, int length,
380                      int* indices, double* doubles) {
381      lpx_set_mat_row(lp, row_iter_map[row_it], length, indices, doubles);
382    }
383    using Parent::setColCoeffs;
384    void setColCoeffs(ColIt col_it, int length,
385                      int* indices, double* doubles) {
386      lpx_set_mat_col(lp, col_iter_map[col_it], length, indices, doubles);
387    }
388    //     //pair<RowIt, double>-bol kell megadni egy std range-et
389    //     /// \e
390    //     template <typename Begin, typename End>
391    //     void setColCoeffs(const ColIt& col_it,
392    //                Begin begin, End end) {
393    //       int mem_length=1+lpx_get_num_rows(lp);
394    //       int* indices = new int[mem_length];
395    //       double* doubles = new double[mem_length];
396    //       int length=0;
397    //       for ( ; begin!=end; ++begin) {
398    //  ++length;
399    //  indices[length]=row_iter_map[begin->first];
400    //  doubles[length]=begin->second;
401    //       }
402    //       lpx_set_mat_col(lp, col_iter_map[col_it], length, indices, doubles);
403    //       delete [] indices;
404    //       delete [] doubles;
405    //     }
406    //     //pair<ColIt, double>-bol kell megadni egy std range-et
407    //     /// \e
408    //     template <typename Begin, typename End>
409    //     void setRowCoeffs(const RowIt& row_it,
410    //                Begin begin, End end) {
411    //       int mem_length=1+lpx_get_num_cols(lp);
412    //       int* indices = new int[mem_length];
413    //       double* doubles = new double[mem_length];
414    //       int length=0;
415    //       for ( ; begin!=end; ++begin) {
416    //  ++length;
417    //  indices[length]=col_iter_map[begin->first];
418    //  doubles[length]=begin->second;
419    //       }
420    //       lpx_set_mat_row(lp, row_iter_map[row_it], length, indices, doubles);
421    //       delete [] indices;
422    //       delete [] doubles;
423    //     }
424    /// \e
425    void eraseCol(const ColIt& col_it) {
426      col_iter_map.set(col_it, VALID_ID, INVALID_ID);
427      int cols[2];
428      cols[1]=col_iter_map[col_it];
429      lpx_del_cols(lp, 1, cols);
430      col_iter_map[col_it]=0; //glpk specifikus
431      ColIt it;
432      for (col_iter_map.first(it, VALID_ID);
433           col_iter_map.valid(it); col_iter_map.next(it)) {
434        if (col_iter_map[it]>cols[1]) --col_iter_map[it];
435      }
436    }
437    /// \e
438    void eraseRow(const RowIt& row_it) {
439      row_iter_map.set(row_it, VALID_ID, INVALID_ID);
440      int rows[2];
441      rows[1]=row_iter_map[row_it];
442      lpx_del_rows(lp, 1, rows);
443      row_iter_map[row_it]=0; //glpk specifikus
444      RowIt it;
445      for (row_iter_map.first(it, VALID_ID);
446           row_iter_map.valid(it); row_iter_map.next(it)) {
447        if (row_iter_map[it]>rows[1]) --row_iter_map[it];
448      }
449    }
450    /// \e
451    void setColBounds(const ColIt& col_it, int bound_type,
452                      double lo, double up) {
453      lpx_set_col_bnds(lp, col_iter_map[col_it], bound_type, lo, up);
454    }
455    /// \e
456    double getObjCoef(const ColIt& col_it) {
457      return lpx_get_obj_coef(lp, col_iter_map[col_it]);
458    }
459    /// \e
460    void setRowBounds(const RowIt& row_it, int bound_type,
461                      double lo, double up) {
462      lpx_set_row_bnds(lp, row_iter_map[row_it], bound_type, lo, up);
463    }
464    /// \e
465    void setObjCoef(const ColIt& col_it, double obj_coef) {
466      lpx_set_obj_coef(lp, col_iter_map[col_it], obj_coef);
467    }
468    /// \e
469    void solveSimplex() { lpx_simplex(lp); }
470    /// \e
471    void solvePrimalSimplex() { lpx_simplex(lp); }
472    /// \e
473    void solveDualSimplex() { lpx_simplex(lp); }
474    /// \e
475    double getPrimal(const ColIt& col_it) {
476      return lpx_get_col_prim(lp, col_iter_map[col_it]);
477    }
478    /// \e
479    double getObjVal() { return lpx_get_obj_val(lp); }
480    /// \e
481    int rowNum() const { return lpx_get_num_rows(lp); }
482    /// \e
483    int colNum() const { return lpx_get_num_cols(lp); }
484    /// \e
485    int warmUp() { return lpx_warm_up(lp); }
486    /// \e
487    void printWarmUpStatus(int i) {
488      switch (i) {
489      case LPX_E_OK: cout << "LPX_E_OK" << endl; break;
490      case LPX_E_EMPTY: cout << "LPX_E_EMPTY" << endl; break;   
491      case LPX_E_BADB: cout << "LPX_E_BADB" << endl; break;
492      case LPX_E_SING: cout << "LPX_E_SING" << endl; break;
493      }
494    }
495    /// \e
496    int getPrimalStatus() { return lpx_get_prim_stat(lp); }
497    /// \e
498    void printPrimalStatus(int i) {
499      switch (i) {
500      case LPX_P_UNDEF: cout << "LPX_P_UNDEF" << endl; break;
501      case LPX_P_FEAS: cout << "LPX_P_FEAS" << endl; break;     
502      case LPX_P_INFEAS: cout << "LPX_P_INFEAS" << endl; break;
503      case LPX_P_NOFEAS: cout << "LPX_P_NOFEAS" << endl; break;
504      }
505    }
506    /// \e
507    int getDualStatus() { return lpx_get_dual_stat(lp); }
508    /// \e
509    void printDualStatus(int i) {
510      switch (i) {
511      case LPX_D_UNDEF: cout << "LPX_D_UNDEF" << endl; break;
512      case LPX_D_FEAS: cout << "LPX_D_FEAS" << endl; break;     
513      case LPX_D_INFEAS: cout << "LPX_D_INFEAS" << endl; break;
514      case LPX_D_NOFEAS: cout << "LPX_D_NOFEAS" << endl; break;
515      }
516    }
517    /// Returns the status of the slack variable assigned to row \c row_it.
518    int getRowStat(const RowIt& row_it) {
519      return lpx_get_row_stat(lp, row_iter_map[row_it]);
520    }
521    /// \e
522    void printRowStatus(int i) {
523      switch (i) {
524      case LPX_BS: cout << "LPX_BS" << endl; break;
525      case LPX_NL: cout << "LPX_NL" << endl; break;     
526      case LPX_NU: cout << "LPX_NU" << endl; break;
527      case LPX_NF: cout << "LPX_NF" << endl; break;
528      case LPX_NS: cout << "LPX_NS" << endl; break;
529      }
530    }
531    /// Returns the status of the variable assigned to column \c col_it.
532    int getColStat(const ColIt& col_it) {
533      return lpx_get_col_stat(lp, col_iter_map[col_it]);
534    }
535    /// \e
536    void printColStatus(int i) {
537      switch (i) {
538      case LPX_BS: cout << "LPX_BS" << endl; break;
539      case LPX_NL: cout << "LPX_NL" << endl; break;     
540      case LPX_NU: cout << "LPX_NU" << endl; break;
541      case LPX_NF: cout << "LPX_NF" << endl; break;
542      case LPX_NS: cout << "LPX_NS" << endl; break;
543      }
544    }
545  };
546 
547  /// @}
548
549} //namespace lemon
550
551#endif //LEMON_LP_SOLVER_WRAPPER_H
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