summaryrefslogtreecommitdiff
path: root/macros/symphonymat.sci
blob: 5aab6e53a74cb765df81e5d377aae4d5c946c9dd (plain)
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
65
66
67
68
69
70
71
72
73
74
75
76
77
78
79
80
81
82
83
84
85
86
87
88
89
90
91
92
93
94
95
96
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
129
130
131
132
133
134
135
136
137
138
139
140
141
142
143
144
145
146
147
148
149
150
151
152
153
154
155
156
157
158
159
160
161
162
163
164
165
166
167
168
169
170
171
172
173
174
175
176
177
178
179
180
181
182
183
184
185
186
187
188
189
190
191
192
193
194
195
196
197
198
199
200
201
202
203
204
205
206
207
208
209
210
211
212
213
214
215
216
217
218
219
220
221
222
223
224
225
226
227
228
229
230
231
232
233
234
235
236
237
238
239
240
241
242
243
244
245
246
247
248
249
250
251
252
253
254
255
256
257
258
259
260
261
262
263
264
265
266
267
268
269
270
271
272
273
274
275
276
277
278
279
280
281
282
283
284
285
286
287
288
289
290
291
292
293
294
295
296
297
298
299
300
301
302
303
304
305
306
307
308
309
310
311
312
313
314
315
316
317
318
319
320
321
322
323
324
325
326
327
328
329
330
331
332
333
334
335
336
337
338
339
340
341
342
343
344
345
346
347
348
349
350
351
352
353
354
355
356
// Copyright (C) 2015 - IIT Bombay - FOSSEE
//
// Author: Harpreet Singh
// Organization: FOSSEE, IIT Bombay
// Email: harpreet.mertia@gmail.com
// This file must be used under the terms of the CeCILL.
// This source file is licensed as described in the file COPYING, which
// you should have received as part of this distribution.  The terms
// are also available at
// http://www.cecill.info/licences/Licence_CeCILL_V2-en.txt

function [xopt,fopt,status,iter] = symphonymat (varargin)
  // Solves a mixed integer linear programming constrained optimization problem in intlinprog format.
  //
  //   Calling Sequence
  //   xopt = symphonymat(f,intcon,A,b)
  //   xopt = symphonymat(f,intcon,A,b,Aeq,beq)
  //   xopt = symphonymat(f,intcon,A,b,Aeq,beq,lb,ub)
  //   xopt = symphonymat(f,intcon,A,b,Aeq,beq,lb,ub,options)
  //   [xopt,fopt,status,output] = symphonymat( ... )
  //   
  //   Parameters
  //   f : a vector of doubles, contains coefficients of the variables in the objective 
  //   intcon : Vector of integer constraints, specified as a vector of positive integers. The values in intcon indicate the components of the decision variable x that are integer-valued. intcon has values from 1 through number of variable.
  //   A : Linear inequality constraint matrix, specified as a matrix of doubles. A represents the linear coefficients in the constraints A*x ≤ b. A has size M-by-N, where M is the number of constraints and N is number of variables
  //   b : Linear inequality constraint vector, specified as a vector of doubles. b represents the constant vector in the constraints A*x ≤ b. b has length M, where A is M-by-N
  //   Aeq : Linear equality constraint matrix, specified as a matrix of doubles. Aeq represents the linear coefficients in the constraints Aeq*x = beq. Aeq has size Meq-by-N, where Meq is the number of constraints and N is number of variables
  //   beq : Linear equality constraint vector, specified as a vector of doubles. beq represents the constant vector in the constraints Aeq*x = beq. beq has length Meq, where Aeq is Meq-by-N. 
  //   lb : Lower bounds, specified as a vector or array of doubles. lb represents the lower bounds elementwise in lb ≤ x ≤ ub.
  //   ub : Upper bounds, specified as a vector or array of doubles. ub represents the upper bounds elementwise in lb ≤ x ≤ ub.
  //   options : a list containing the the parameters to be set.
  //   xopt : a vector of double, the computed solution of the optimization problem
  //   fopt : a doubles, the function value at x
  //   status : status flag from symphony.
  //   output : The output data structure contains detailed informations about the optimization process.
  //   
  //   Description
  //   Search the minimum or maximum of a constrained mixed integer linear programming optimization problem specified by :
  //   find the minimum or maximum of f(x) such that 
  //
  //   <latex>
  //    \begin{eqnarray}
  //    &\mbox{min}_{x}
  //    & f(x) \\
  //    & \text{subject to} & A.x \leq b \\
  //    & & Aeq.x \leq beq \\
  //    & & lb \leq x \leq ub \\
  //    \end{eqnarray}
  //   </latex>
  //   
  //   We are calling SYMPHONY written in C by gateway files for the actual computation. SYMPHONY was originally written by ​Ted Ralphs, ​Menal Guzelsoy and ​Ashutosh Mahajan.
  //
  // Examples
  //    // Objective function
  //    c = [350*5,330*3,310*4,280*6,500,450,400,100]';
  //    // Lower Bound of variable
  //    lb = repmat(0,1,8);
  //    // Upper Bound of variables
  //    ub = [repmat(1,1,4) repmat(%inf,1,4)];
  //    // Constraint Matrix
  //    Aeq = [5,3,4,6,1,1,1,1;
  //                 5*0.05,3*0.04,4*0.05,6*0.03,0.08,0.07,0.06,0.03;
  //                 5*0.03,3*0.03,4*0.04,6*0.04,0.06,0.07,0.08,0.09;]
  //    beq = [ 25, 1.25, 1.25]
  //    intcon = [1 2 3 4];
  //    // Calling Symphony
  //    [x,f,status,output] = symphonymat(c,intcon,[],[],Aeq,beq,lb,ub)
  //
  // Examples 
  //    // An advanced case where we set some options in symphony
  //    // This problem is taken from 
  //    // P.C.Chu and J.E.Beasley 
  //    // "A genetic algorithm for the multidimensional knapsack problem",
  //    // Journal of Heuristics, vol. 4, 1998, pp63-86.
  //    // The problem to be solved is:
  //    // Max  sum{j=1,...,n} p(j)x(j)
  //    // st   sum{j=1,...,n} r(i,j)x(j) <= b(i)       i=1,...,m
  //    //                     x(j)=0 or 1
  //    // The function to be maximize i.e. P(j)
  //    objCoef = -1*[   504 803 667 1103 834 585 811 856 690 832 846 813 868 793 ..
  //            825 1002 860 615 540 797 616 660 707 866 647 746 1006 608 ..
  //            877 900 573 788 484 853 942 630 591 630 640 1169 932 1034 ..
  //            957 798 669 625 467 1051 552 717 654 388 559 555 1104 783 ..
  //            959 668 507 855 986 831 821 825 868 852 832 828 799 686 ..
  //            510 671 575 740 510 675 996 636 826 1022 1140 654 909 799 ..
  //            1162 653 814 625 599 476 767 954 906 904 649 873 565 853 1008 632]';
  //    //Constraint Matrix
  //    conMatrix = [   //Constraint 1
  //                    42 41 523 215 819 551 69 193 582 375 367 478 162 898 ..
  //                    550 553 298 577 493 183 260 224 852 394 958 282 402 604 ..
  //                    164 308 218 61 273 772 191 117 276 877 415 873 902 465 ..
  //                    320 870 244 781 86 622 665 155 680 101 665 227 597 354 ..
  //                    597 79 162 998 849 136 112 751 735 884 71 449 266 420 ..
  //                    797 945 746 46 44 545 882 72 383 714 987 183 731 301 ..
  //                    718 91 109 567 708 507 983 808 766 615 554 282 995 946 651 298;
  //                    //Constraint 2
  //                    509 883 229 569 706 639 114 727 491 481 681 948 687 941 ..
  //                    350 253 573 40 124 384 660 951 739 329 146 593 658 816 ..
  //                    638 717 779 289 430 851 937 289 159 260 930 248 656 833 ..
  //                    892 60 278 741 297 967 86 249 354 614 836 290 893 857 ..
  //                    158 869 206 504 799 758 431 580 780 788 583 641 32 653 ..
  //                    252 709 129 368 440 314 287 854 460 594 512 239 719 751 ..
  //                    708 670 269 832 137 356 960 651 398 893 407 477 552 805 881 850;
  //                    //Constraint 3
  //                    806 361 199 781 596 669 957 358 259 888 319 751 275 177 ..
  //                    883 749 229 265 282 694 819 77 190 551 140 442 867 283 ..
  //                    137 359 445 58 440 192 485 744 844 969 50 833 57 877 ..
  //                    482 732 968 113 486 710 439 747 174 260 877 474 841 422 ..
  //                    280 684 330 910 791 322 404 403 519 148 948 414 894 147 ..
  //                    73 297 97 651 380 67 582 973 143 732 624 518 847 113 ..
  //                    382 97 905 398 859 4 142 110 11 213 398 173 106 331 254 447 ;
  //                    //Constraint 4
  //                    404 197 817 1000 44 307 39 659 46 334 448 599 931 776 ..
  //                    263 980 807 378 278 841 700 210 542 636 388 129 203 110 ..
  //                    817 502 657 804 662 989 585 645 113 436 610 948 919 115 ..
  //                    967 13 445 449 740 592 327 167 368 335 179 909 825 614 ..
  //                    987 350 179 415 821 525 774 283 427 275 659 392 73 896 ..
  //                    68 982 697 421 246 672 649 731 191 514 983 886 95 846 ..
  //                    689 206 417 14 735 267 822 977 302 687 118 990 323 993 525 322;
  //                    //Constrain 5
  //                    475 36 287 577 45 700 803 654 196 844 657 387 518 143 ..
  //                    515 335 942 701 332 803 265 922 908 139 995 845 487 100 ..
  //                    447 653 649 738 424 475 425 926 795 47 136 801 904 740 ..
  //                    768 460 76 660 500 915 897 25 716 557 72 696 653 933 ..
  //                    420 582 810 861 758 647 237 631 271 91 75 756 409 440 ..
  //                    483 336 765 637 981 980 202 35 594 689 602 76 767 693 ..
  //                    893 160 785 311 417 748 375 362 617 553 474 915 457 261 350 635 ;
  //     ];
  //    nbVar = size(objCoef,1)
  //    conUB=[11927 13727 11551 13056 13460 ];
  //    // Lower Bound of variables
  //    lb = repmat(0,1,nbVar)
  //    // Upper Bound of variables
  //    ub = repmat(1,1,nbVar)
  //    // Lower Bound of constrains
  //    intcon = [];
  //    for i = 1:nbVar
  //        intcon = [intcon i];
  //    end
  //    options = list("time_limit", 25);
  //    // The expected solution :
  //    // Output variables
  //    xopt = [0 1 1 0 0 1 0 1 0 1 0 0 0 0 0 0 0 1 0 0 0 0 1 0 1 1 0 1 1 0 1 ..
  //            0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 1 1 ..
  //            0 0 1 0 0 1 0 1 0 0 1 0 0 1 0 1 0 0 0 0 0 1 1 0 0 0 0 0 1 1 0 0 1 0 0 1 0]
  //    // Optimal value
  //    fopt = [ 24381 ]
  //    // Calling Symphony
  //    [x,f,status,output] = symphonymat(objCoef,intcon,conMatrix,conUB,[],[],lb,ub,options);
  // 
  // Authors
  // Keyur Joshi, Saikiran, Iswarya, Harpreet Singh
    
    
//To check the number of input and output argument
   [lhs , rhs] = argn();
	
//To check the number of argument given by user
   if ( rhs < 4 | rhs == 5 | rhs == 7 | rhs > 9 ) then
    errmsg = msprintf(gettext("%s: Unexpected number of input arguments : %d provided while should be in the set [4 6 8 9]"), "Symphony", rhs);
    error(errmsg)
   end
   
   
   objCoef = varargin(1)
   intcon = varargin(2)
   A = varargin(3)
   b = varargin(4)

   if (size(objCoef,2)~=1) then
	errmsg = msprintf(gettext("%s: Objective Coefficients should be a column matrix"), "Symphonymat");
	error(errmsg);
   end


   nbVar = size(objCoef,1);

   if ( rhs<5 ) then
      Aeq = []
      beq = []
   else
      Aeq = varargin(5);
      beq = varargin(6);
   end
   
   if ( rhs<7 ) then
      lb = repmat(-%inf,1,nbVar);
      ub = repmat(%inf,1,nbVar);
   else
      lb = varargin(7);
      ub = varargin(8);
   end
   
   if (rhs<9|size(varargin(9))==0) then
      options = list();
   else
      options = varargin(9);
   end

// Check if the user gives empty matrix
    if (size(lb,2)==0) then
        lb = repmat(-%inf,nbVar,1);
    end
    
    if (size(intcon,2)==0) then
        intcon = 0;
    end
    
    if (size(ub,2)==0) then
        ub = repmat(%inf,nbVar,1);
    end

// Calculating the size of equality and inequality constraints
   nbConInEq = size(A,1);
   nbConEq = size(Aeq,1);

// Check if the user gives row vector 
// and Changing it to a column matrix

   if (size(lb,2)== [nbVar]) then
	lb = lb';
   end

   if (size(ub,2)== [nbVar]) then
	ub = ub';
   end

   if (size(b,2)== [nbConInEq]) then
	b = b';
   end

   if (size(beq,2)== [nbConEq]) then
	beq = beq';
   end

    for i=1:size(intcon,2)
	if(intcon(i)>nbVar) then
		errmsg = msprintf(gettext("%s: The values inside intcon should not exceed total number of variable "), "Symphonymat");
		error(errmsg);
	end

	if (intcon(i)<1) then
		errmsg = msprintf(gettext("%s: The values inside intcon should be greater than 0 "), "Symphonymat");
		error(errmsg);
	end

	if(modulo(intcon(i),1)) then
		errmsg = msprintf(gettext("%s: The values inside intcon should be integer "), "Symphonymat");
		error(errmsg);
	end
    end

   //Check the size of inequality constraint which should equal to the number of inequality constraints
   if ( size(A,2) ~= nbVar & size(A,2) ~= 0) then
	errmsg = msprintf(gettext("%s: The size of inequality constraint is not equal to the number of variables"), "Symphonymat");
	error(errmsg);
   end


   //Check the size of lower bound of inequality constraint which should equal to the number of constraints
   if ( size(b,1) ~= size(A,1)) then
      errmsg = msprintf(gettext("%s: The Lower Bound of inequality constraint is not equal to the number of constraint"), "Symphonymat");
      error(errmsg);
   end

   //Check the size of equality constraint which should equal to the number of inequality constraints
   if ( size(Aeq,2) ~= nbVar & size(Aeq,2) ~= 0) then
	errmsg = msprintf(gettext("%s: The size of equality constraint is not equal to the number of variables"), "Symphonymat");
	error(errmsg);
   end

   //Check the size of upper bound of equality constraint which should equal to the number of constraints
   if ( size(beq,1) ~= size(Aeq,1)) then
	errmsg = msprintf(gettext("%s: The equality constraint upper bound is not equal to the number of equality constraint"), "Symphonymat");
	error(errmsg);
   end

   //Check the size of Lower Bound which should equal to the number of variables
   if ( size(lb,1) ~= nbVar) then
      errmsg = msprintf(gettext("%s: The Lower Bound is not equal to the number of variables"), "Symphonymat");
      error(errmsg);
   end

   //Check the size of Upper Bound which should equal to the number of variables
   if ( size(ub,1) ~= nbVar) then
      errmsg = msprintf(gettext("%s: The Upper Bound is not equal to the number of variables"), "Symphonymat");
      error(errmsg);
   end
   
   if (type(options) ~= 15) then
      errmsg = msprintf(gettext("%s: Options should be a list "), "Symphonymat");
      error(errmsg);
   end
   

   if (modulo(size(options),2)) then
	errmsg = msprintf(gettext("%s: Size of parameters should be even"), "Symphonymat");
	error(errmsg);
   end

   //Check if the user gives a matrix instead of a vector
   
   if ((size(intcon,1)~=1)& (size(intcon,2)~=1)) then
      errmsg = msprintf(gettext("%s: intcon should be a vector"), "symphonymat");
      error(errmsg); 
   end
   
   if (size(lb,1)~=1)& (size(lb,2)~=1) then
      errmsg = msprintf(gettext("%s: Lower Bound should be a vector"), "symphonymat");
      error(errmsg); 
   end
   
   if (size(ub,1)~=1)& (size(ub,2)~=1) then
      errmsg = msprintf(gettext("%s: Upper Bound should be a vector"), "symphonymat");
      error(errmsg); 
   end
   
   if (nbConInEq) then
        if ((size(b,1)~=1)& (size(b,2)~=1)) then
            errmsg = msprintf(gettext("%s: Constraint Lower Bound should be a vector"), "symphonymat");
            error(errmsg); 
        end
    end
    
    if (nbConEq) then
        if (size(beq,1)~=1)& (size(beq,2)~=1) then
            errmsg = msprintf(gettext("%s: Constraint Upper Bound should be a vector"), "symphonymat");
            error(errmsg); 
        end
   end
  

    //Changing the inputs in symphony's format 
    conMatrix = [A;Aeq]
    nbCon = size(conMatrix,1);
    conLB = [repmat(-%inf,size(A,1),1); beq];
    conUB = [b;beq] ;
    
    isInt = repmat(%f,1,nbVar);
    // Changing intcon into column vector
    intcon = intcon(:);
    for i=1:size(intcon,1)
        isInt(intcon(i)) = %t
    end
    
    objSense = 1;

    //Changing into row vector
    lb = lb';
    ub = ub';
    objCoef = objCoef';
    

   [xopt,fopt,status,iter] = symphony_call(nbVar,nbCon,objCoef,isInt,lb,ub,conMatrix,conLB,conUB,objSense,options);

endfunction