# Simple optimization in cvxopt CVXOPT glpk MILP. No optimization

I'm using CVXOPT to solve this simple optimization problem:

``````maximize X1 + X2
s.t:
X2 + X6      = 2
X1 + X2 + X5 = 2
X1 + X4      = 2
X1           >=0
X2           >=0
``````

Obviously this has a really simple solution

`````` X1 = 1
X2 = 1
``````

(all the rest are 0)

However, cvxopt get it completely wrong. this is what I do:

``````>>> print A
[ 0.00e+00  1.00e+00  0.00e+00  0.00e+00  0.00e+00  1.00e+00]
[ 1.00e+00  1.00e+00  0.00e+00  0.00e+00  1.00e+00  0.00e+00]
[ 1.00e+00  0.00e+00  0.00e+00  1.00e+00  0.00e+00  0.00e+00]

>>> print b
[ 2.00e+00]
[ 2.00e+00]
[ 2.00e+00]

>>> print G
[-1.00e+00  0.00e+00  0.00e+00  0.00e+00  0.00e+00  0.00e+00]
[ 0.00e+00 -1.00e+00  0.00e+00  0.00e+00  0.00e+00  0.00e+00]

>>> print h
[ 0.00e+00]
[ 0.00e+00]

>>> print c
[-1.00e+00]
[-1.00e+00]
[ 0.00e+00]
[ 0.00e+00]
[ 0.00e+00]
[ 0.00e+00]
``````

(all of the above are "matrix" type of cvxopt)

print glpk.ilp(c,G,h,A,b,I=set([0,1,2,3,4,5]))[1]

``````GLPK Integer Optimizer, v4.43
5 rows, 6 columns, 9 non-zeros
6 integer variables, none of which are binary

Preprocessing...
3 rows, 5 columns, 7 non-zeros
5 integer variables, none of which are binary
Scaling...
A: min|aij| =  1.000e+00  max|aij| =  1.000e+00  ratio =  1.000e+00
Problem data seem to be well scaled
Constructing initial basis...
Size of triangular part = 3
Solving LP relaxation...

GLPK Simplex Optimizer, v4.43

3 rows, 5 columns, 7 non-zeros
*     0: obj =   0.000000000e+00  infeas =  0.000e+00 (0)
PROBLEM HAS UNBOUNDED SOLUTION
None
``````
-
Unless you are omitting something in your problem formulation above, there is not one but infinitely many solutions to the problem if you are assuming X1 and X2 real, and three solutions when you require integer values: (2,0), (1,1) and (0,2). –  Anders Gustafsson Sep 25 '12 at 13:05
Yes, that is true. I just fixed this moments a go. Thanks –  Zahy Sep 27 '12 at 7:44
@Zahy Would you mind posting the code that fixed your problem? –  user815423426 Oct 31 '12 at 15:25
I do not have access to it anymore. But CVXOPT was right, I was wrong! there is an unbounded solution (the array inputs were wrong) –  Zahy Nov 1 '12 at 18:02

Here is the code implementing the above:

``````import cvxopt.glpk
import cvxopt
c=cvxopt.matrix([1,1,0,0,0,0])
G=cvxopt.matrix([[1.0,0,0,0,0,0], [0,1,0,0,0,0]])
h=cvxopt.matrix([0.0,0.0])
A=cvxopt.matrix([[0.0,1,0,0,0,6], [1,1,0,0,1,0], [1,0,0,1,0,0]])
b=cvxopt.matrix([2.0, 2, 2])
(status, c)=cvxopt.glpk.ilp(-c,-(G.T),-h,A.T,b,I=set([0,1,2,3,4,5]))
print(status, c)
``````

And the result is:

``````optimal [ 0.00e+00]
[ 2.00e+00]
[ 0.00e+00]
[ 2.00e+00]
[ 0.00e+00]
[ 0.00e+00]
``````

I'm not sure how to get all the solutions ...

-