# Is there a quadratic programming library in C++? [closed]

The only Google search result I found is QuadProg++ but it can not solve the quadratic programming problem whose matrix is not applicable for Cholesky decomposition.

So can anyone give me some suggestion on other library? Thanks.

-

## closed as off-topic by chue x, Benjamin Bannier, showdev, Gert Arnold, NT3RPDec 30 '13 at 18:02

This question appears to be off-topic. The users who voted to close gave this specific reason:

• "Questions asking us to recommend or find a tool, library or favorite off-site resource are off-topic for Stack Overflow as they tend to attract opinionated answers and spam. Instead, describe the problem and what has been done so far to solve it." – chue x, Benjamin Bannier, showdev, Gert Arnold, NT3RP
If this question can be reworded to fit the rules in the help center, please edit the question.

Sorry for stating the obvious but I had to check Wikipedia to find out what quadratic programming is and I saw it contains references to a few implementations, have you checked those? Or maybe hqp.sourceforge.net/index.html or gnu.org/s/gsl would help? –  rve Nov 6 '11 at 8:04
@rve I check the gsl, it does not have a quadratic programming solver function. I also checked the wiki, most of them are either not written in C/c++ or very hard to setup.. I will check the hqp to see whether it work, thanks –  Daniel Gao Nov 6 '11 at 15:07
How could a matrix be non-applicable to Cholesky decomposition? Any symmetric positive-semidefinite matrix is applicable (and decomposition takes ~n^3/3 FLOPs). Expression \$x^TQx\$ can always be (re-)written with \$Q\$ being symmetric. Do you mean, that it is not positive-semidefinite? –  fiktor May 28 '12 at 8:23
QuadProg++ requires the matrix to be positive definite, not positive semi-definite. –  Ben-Uri Jul 19 '12 at 17:05
Did you find a a solution for this? If so, can you please post it here? –  Ben-Uri Jul 19 '12 at 17:10
show 1 more comment

LAPACK has a number of Cholesky decomposition routines (they call it Cholesky factorization). There are C++ wrappers available for LAPACK (see this SO question for a list).

The answer from Anycom in that post is a bit cryptic, but he meant that there are LAPACK bindings that can be used together with Boost's linear algebra library, uBLAS.

I've found this library: OOQP (Object-Oriented Software for Quadratic Programming). If you scroll down that page, you'll find a research paper and a user guide. There seems to be a C++ API for that library. Hope this helps.

-
But this does not solve my problem. The Symmetric matrix in the quadratic programming problem I am trying to solve is not applicable for Cholesky decomposition. –  Daniel Gao Nov 6 '11 at 18:00
Oops, I didn't read your question carefully enough. Sorry. –  Emile Cormier Nov 6 '11 at 18:03
@DanielGao: Updated my answer. –  Emile Cormier Nov 6 '11 at 18:17

CGAL looks great for quadratic programming. There is even a manual.

``````  // by default, we have a nonnegative QP with Ax <= b
Program qp (CGAL::SMALLER, true, 0, false, 0);

// now set the non-default entries:
const int X = 0;
const int Y = 1;
qp.set_a(X, 0,  1); qp.set_a(Y, 0, 1); qp.set_b(0, 7);  //  x + y  <= 7
qp.set_a(X, 1, -1); qp.set_a(Y, 1, 2); qp.set_b(1, 4);  // -x + 2y <= 4
qp.set_u(Y, true, 4);                                   //       y <= 4
qp.set_d(X, X, 2); qp.set_d (Y, Y, 8); // !!specify 2D!!    x^2 + 4 y^2
qp.set_c(Y, -32);                                       // -32y
qp.set_c0(64);                                          // +64

// solve the program, using ET as the exact type
``````

Code from the first example.

-

There are several libraries that include QP solvers. There are both open-source and commercial options. The existing answers list a few of these. I'd like to clarify the issue with the matrix.

I assume you are referring to the objective matrix. The constraint matrix only needs to lead to a non-empty feasible set. You mentioned that the matrix is not suitable for Cholesky decomposition. Since the Cholesky decomposition can be formed for any positive definite matrix, the implication is that your matrix is not positive definite.

If the matrix is positive semi-definite (i.e. it has one or more zero eigenvalues) then the problem is a convex QP and can be solved efficiently. However, many solvers require a positive definite objective. Since the objective of a positive semi-definite QP has a non-trivial nullspace, there may be many solutions. In fact, the set of solutions can even be unbounded. Numerical algorithms will only give an approximate solution anyways, so it is rarely important that the matrix have eigenvalues that are exactly zero. You can make the matrix positive definite by adding a diagonal matrix with a small positive value on the diagonal. This will essentially select the solution with the smallest 2-norm. In practice, it is a good idea to do this even when the matrix is positive definite because matrices that have eigenvalues close to zero can often cause problems with numerical solvers. How much diagonal to add in is a tradeoff between stability and accuracy.

If the matrix is indefinite (i.e. it has even one negative eigenvalue) then the problem is NP-hard. That means any codes based on currently available algorithms will have unreasonable worst-case running times even for moderate sized problems. If your problem has some special structure or you don't require a globally optimal solution then you might be ok. A typical approach is to look for a convex relaxation.

-
All interesting, but OP was asking for pointers to other libraries, not a dissertation on how to solve QP problems. –  Ted Hopp Dec 30 '13 at 4:40
In this case, it appears that the "dissertation on how to solve QP problems" is what the OP actually needs, whether or not they realize it. –  Zack Dec 30 '13 at 21:34