I would like students to solve a quadratic program in an assignment without them having to install extra software like cvxopt etc. Is there a python implementation available that only depends on NumPy/SciPy?
I ran across a good solution and wanted to get it out there. There is a python implementation of LOQO in the ELEFANT machine learning toolkit out of NICTA (http://elefant.forge.nicta.com.au as of this posting). Have a look at optimization.intpointsolver. This was coded by Alex Smola, and I've used a Cversion of the same code with great success.

1I don't believe the project is active. The download link is broken, but this link works: elefant.forge.nicta.com.au/download/release/0.4/index.html There's a C++ fork of the project at users.cecs.anu.edu.au/~chteo/BMRM.html, but I don't believe it is active either. – Tom Vacek Feb 24 '14 at 19:35
I'm not very familiar with quadratic programming, but I think you can solve this sort of problem just using scipy.optimize
's constrained minimization algorithms. Here's an example:
import numpy as np
from scipy import optimize
from matplotlib import pyplot as plt
from mpl_toolkits.mplot3d.axes3d import Axes3D
# minimize
# F = x[1]^2 + 4x[2]^2 32x[2] + 64
# subject to:
# x[1] + x[2] <= 7
# x[1] + 2x[2] <= 4
# x[1] >= 0
# x[2] >= 0
# x[2] <= 4
# in matrix notation:
# F = (1/2)*x.T*H*x + c*x + c0
# subject to:
# Ax <= b
# where:
# H = [[2, 0],
# [0, 8]]
# c = [0, 32]
# c0 = 64
# A = [[ 1, 1],
# [1, 2],
# [1, 0],
# [0, 1],
# [0, 1]]
# b = [7,4,0,0,4]
H = np.array([[2., 0.],
[0., 8.]])
c = np.array([0, 32])
c0 = 64
A = np.array([[ 1., 1.],
[1., 2.],
[1., 0.],
[0., 1.],
[0., 1.]])
b = np.array([7., 4., 0., 0., 4.])
x0 = np.random.randn(2)
def loss(x, sign=1.):
return sign * (0.5 * np.dot(x.T, np.dot(H, x))+ np.dot(c, x) + c0)
def jac(x, sign=1.):
return sign * (np.dot(x.T, H) + c)
cons = {'type':'ineq',
'fun':lambda x: b  np.dot(A,x),
'jac':lambda x: A}
opt = {'disp':False}
def solve():
res_cons = optimize.minimize(loss, x0, jac=jac,constraints=cons,
method='SLSQP', options=opt)
res_uncons = optimize.minimize(loss, x0, jac=jac, method='SLSQP',
options=opt)
print '\nConstrained:'
print res_cons
print '\nUnconstrained:'
print res_uncons
x1, x2 = res_cons['x']
f = res_cons['fun']
x1_unc, x2_unc = res_uncons['x']
f_unc = res_uncons['fun']
# plotting
xgrid = np.mgrid[2:4:0.1, 1.5:5.5:0.1]
xvec = xgrid.reshape(2, 1).T
F = np.vstack([loss(xi) for xi in xvec]).reshape(xgrid.shape[1:])
ax = plt.axes(projection='3d')
ax.hold(True)
ax.plot_surface(xgrid[0], xgrid[1], F, rstride=1, cstride=1,
cmap=plt.cm.jet, shade=True, alpha=0.9, linewidth=0)
ax.plot3D([x1], [x2], [f], 'og', mec='w', label='Constrained minimum')
ax.plot3D([x1_unc], [x2_unc], [f_unc], 'oy', mec='w',
label='Unconstrained minimum')
ax.legend(fancybox=True, numpoints=1)
ax.set_xlabel('x1')
ax.set_ylabel('x2')
ax.set_zlabel('F')
Output:
Constrained:
status: 0
success: True
njev: 4
nfev: 4
fun: 7.9999999999997584
x: array([ 2., 3.])
message: 'Optimization terminated successfully.'
jac: array([ 4., 8., 0.])
nit: 4
Unconstrained:
status: 0
success: True
njev: 3
nfev: 5
fun: 0.0
x: array([ 2.66453526e15, 4.00000000e+00])
message: 'Optimization terminated successfully.'
jac: array([ 5.32907052e15, 3.55271368e15, 0.00000000e+00])
nit: 3

1I doubt that this is very efficient. I think an implementation of LOQO: An Interior Point Code for Quadratic Programming (citeseer.ist.psu.edu/viewdoc/summary?doi=10.1.1.39.2191) will be faster. – flxb Jun 12 '13 at 11:46

6How hard are the problems you need your students to solve? SLSQP solves my (admittedly rather simple) example in about 1.33msec. It can also handle any combination of bounds, inequality and equality constraints. If your heart is set upon using a particular solver that is optimised for QP then you will probably have to (A) have your students install extra dependencies, or (B) write it yourself. – ali_m Jun 12 '13 at 18:51

Thanks for your follow up. The students should use it to solve an Support Vector Machine problem to compare it to a more efficient algorithm they should implement. It's a convex problem in about 100 variables. I might implement the LOQO, just thought I can't be the first. – flxb Jun 12 '13 at 20:29

1It's worth adding 'jac':(lambda x:A) to the constraint definition, to make the solver more robust. – quant_dev Mar 29 '14 at 21:02

I was trying to implement some basic machine learning algorithms from scratch. SVM was on the todo list but I had no confident to pull it out. After reading your answer, I managed to write a svm of my own (github.com/Sacry/mla_sani/blob/master/mla_sani/supervised/…) and it works pretty as expected. I'm really really appreciated for your answer, thank you very much. – Sacry Jul 20 '18 at 2:12
This might be a late answer, but I found CVXOPT
 http://cvxopt.org/  as the commonly used free python library for Quadratic Programming
. However, it is not easy to install, as it requires the installation of other dependencies.

1Well, as you described, it's not easy to install :) Upvote as my thanks for the suggestion but I think I'll try another options first. – Jim Raynor Apr 16 '14 at 20:25

2@JimRaynor I have no problem installing
cvxopt
directly withpip install cvxopt
in OS X. That's it.pip
takes care of everything. And I have installedcvxopt
in several machines already. Surely you need to have compilers installed, but that's also straightforward and if you are usingscipy
you most likely have them already. In case it helps, I use Anaconda as a Python distribution (which is fully free) and installing Anaconda is also straightforward. You don't need admin privileges and there isn't anything you need to config. Just download it, install it, and it's ready to go. – Amelio VazquezReina Aug 1 '14 at 11:33 
2This library was one of the reasons I switched to Anaconda for the ease of managing the dependencies. I just couldn't install it with pip. If you already have Anaconda, use
conda install c https://conda.anaconda.org/omnia cvxopt
and it's done. I'm on Windows 10 and Python 2.7. – blue_chip Mar 29 '16 at 20:32
mystic
provides a pure python implementation of nonlinear/nonconvex optimization algorithms with advanced constraints functionality that typically is only found in QP solvers. mystic
actually provides more robust constraints than most QP solvers. However, if you are looking for optimization algorithmic speed, then the following is not for you. mystic
is not slow, but it's pure python as opposed to python bindings to C. If you are looking for flexibility and QP constraints functionality in a nonlinear solver, then you might be interested.
"""
Maximize: f = 2*x[0]*x[1] + 2*x[0]  x[0]**2  2*x[1]**2
Subject to: 2*x[0] + 2*x[1] <= 2
2*x[0]  4*x[1] <= 0
x[0]**3 x[1] == 0
where: 0 <= x[0] <= inf
1 <= x[1] <= inf
"""
import numpy as np
import mystic.symbolic as ms
import mystic.solvers as my
import mystic.math as mm
# generate constraints and penalty for a nonlinear system of equations
ieqn = '''
2*x0 + 2*x1 <= 2
2*x0  4*x1 <= 0'''
eqn = '''
x0**3  x1 == 0'''
cons = ms.generate_constraint(ms.generate_solvers(ms.simplify(eqn,target='x1')))
pens = ms.generate_penalty(ms.generate_conditions(ieqn), k=1e3)
bounds = [(0., None), (1., None)]
# get the objective
def objective(x, sign=1):
x = np.asarray(x)
return sign * (2*x[0]*x[1] + 2*x[0]  x[0]**2  2*x[1]**2)
# solve
x0 = np.random.rand(2)
sol = my.fmin_powell(objective, x0, constraint=cons, penalty=pens, disp=True,
bounds=bounds, gtol=3, ftol=1e6, full_output=True,
args=(1,))
print 'x* = %s; f(x*) = %s' % (sol[0], sol[1])
Things to note is that mystic
can generically apply LP, QP, and higher order equality and inequality constraints to any given optimizer, not just a special QP solver. Secondly, mystic
can digest symbolic math, so the ease of defining/entering the constraints is a bit nicer than working with the matrices and derivatives of functions. mystic
depends on numpy
, and will use scipy
if it is installed (however, scipy
is not required). mystic
utilizes sympy
to handle symbolic constraints, but it's also not required for optimization in general.
Output:
Optimization terminated successfully.
Current function value: 2.000000
Iterations: 3
Function evaluations: 103
x* = [ 2. 1.]; f(x*) = 2.0
Get mystic
here: https://github.com/uqfoundation
The qpsolvers package also seems to fit the bill. It only depends on NumPy and can be installed by pip install qpsolvers
. Then, you can do:
from numpy import array, dot
from qpsolvers import solve_qp
M = array([[1., 2., 0.], [8., 3., 2.], [0., 1., 1.]])
P = dot(M.T, M) # quick way to build a symmetric matrix
q = dot(array([3., 2., 3.]), M).reshape((3,))
G = array([[1., 2., 1.], [2., 0., 1.], [1., 2., 1.]])
h = array([3., 2., 2.]).reshape((3,))
# min. 1/2 x^T P x + q^T x with G x <= h
print "QP solution:", solve_qp(P, q, G, h)
You can also try different QP solvers (such as CVXOPT mentioned by Curious) by changing the solver
keyword argument, for example solver='cvxopt'
or solver='osqp'
.
numpy
/scipy
and doesn't require additional software like cvxopt… has one answer that recommendscvxopt
and another (the accepted answer) that recommends what's essentially unmaintained python bindings to another language (i.e. a nonpython implementation). – Mike McKerns Oct 2 '15 at 11:03