Exemple #1
0
def disp_relaxation(f, A, b, cuts=[], sol=None, disj=[], filename=None):
    #TODO: Check sense of inequalities by looking explicitly at
    #      lp.constraintsUpper and lp.constraintsLower
    p = Polyhedron2D(A=A, b=b)
    f.add_polyhedron(p, label='Polyhedron $P$')
    f.set_xlim(p.xlim)
    f.set_ylim(p.ylim)
    pI = p.make_integer_hull()
    f.add_polyhedron(pI,
                     show_int_points=True,
                     color='red',
                     linestyle='dashed',
                     label='Convex hull of integer points')
    for (coeff, r) in cuts:
        f.add_line(coeff, r, p.xlim, p.ylim, color='green', linestyle='dashed')
    for (coeff, r) in disj:
        f.add_line(coeff, r, p.xlim, p.ylim, color='red', linestyle='dashed')
        f.add_line(coeff,
                   r + 1,
                   p.xlim,
                   p.ylim,
                   color='red',
                   linestyle='dashed')
    if sol is not None:
        f.add_point(sol, radius=.05)
    f.show(filename=filename)
Exemple #2
0
numCons = 4
#points = [[0, 0], [3, 4], [8, 6], [6, 1]]
points = None
rays = []
A1 = [[1, 1], [4, -10], [-2, -2], [-6, -2], [-1, 4]]
A2 = [[-7, 1], [0, -1], [1, -1], [4, 1], [0, 1], [-1, 5]]
b1 = [8, -3, -9, -19, 12]
b2 = [-13, -1, 3, 27, 5, 20]
sense = ('Min', '<=')
integerIndices = [0, 1]
c = [1, 0]
cuts = None
rhs = None
obj_val = 2

p1 = Polyhedron2D(A=A1, b=b1)
p2 = Polyhedron2D(A=A2, b=b2)
sR = p2.make_integer_hull()

f = Figure()
f.add_polyhedron(p1,
                 label='$\mathcal{P}^{\,\prime}$',
                 color='blue',
                 show_int_points=True)
f.add_polyhedron(p2,
                 label='$\mathcal{P}^{\,\prime\prime}$',
                 color='black',
                 show_int_points=True)
f.add_polyhedron(
    sR,
    label=
Exemple #3
0
    def __init__(self,
                 module_name=None,
                 file_name=None,
                 A=None,
                 b=None,
                 c=None,
                 points=None,
                 rays=None,
                 sense=None,
                 integerIndices=None,
                 numVars=None):

        if file_name is not None:
            # We got a file name, so ignore everything else and read in the instance
            lp = CyClpSimplex()
            lp.extractCyLPModel(file_name)
            self.integerIndices = [
                i for (i, j) in enumerate(lp.integerInformation) if j == True
            ]
            infinity = lp.getCoinInfinity()
            A = lp.coefMatrix
            b = CyLPArray([0 for _ in range(lp.nRows)])
            for i in range(lp.nRows):
                if lp.constraintsLower[i] > -infinity:
                    if lp.constraintsUpper[i] < infinity:
                        raise Exception('Cannot handle ranged constraints')
                    b[i] = -lp.constraintsLower[i]
                    for j in range(lp.nCols):
                        A[i, j] = -A[i, j]
                elif lp.constraintsUpper[i] < infinity:
                    b[i] = lp.constraintsUpper[i]
                else:
                    raise Exception('Constraint with no bounds detected')
            x = lp.addVariable('x', lp.nCols)
            lp += A * x <= b
            lp += x <= lp.variablesUpper
            lp += x >= lp.variablesLower
            lp.objective = lp.objective
            self.sense = '<='
            numVars = lp.nCols
        else:
            min_or_max = None
            if module_name is not None:
                # We got a module name, read the data from there
                mip = ilib.import_module(module_name)
                self.A = mip.A if hasattr(mip, 'A') else None
                self.b = mip.b if hasattr(mip, 'b') else None
                points = mip.points if hasattr(mip, 'points') else None
                rays = mip.rays if hasattr(mip, 'rays') else None
                self.c = mip.c if hasattr(mip, 'c') else None
                self.sense = mip.sense[1] if hasattr(mip, 'sense') else None
                min_or_max = mip.sense[0] if hasattr(mip, 'sense') else None
                self.integerIndices = mip.integerIndices if hasattr(
                    mip, 'integerIndices') else None
                x_u = CyLPArray(mip.x_u) if hasattr(mip, 'x_u') else None
                numVars = mip.numVars if hasattr(mip, 'numVars') else None
                self.x_sep = mip.x_sep if hasattr(mip, 'x_sep') else None
                if numVars is None and mip.A is not None:
                    numVars = len(mip.A)

                if numVars is None:
                    raise "Must specify number of variables when problem is not"
            else:
                self.A = A
                self.b = b
                self.c = c
                self.points = points
                self.rays = rays
                if sense is not None:
                    self.sense = sense[1]
                    min_or_max = sense[0]
                self.integerIndices = integerIndices
                x_u = None

            lp = CyClpSimplex()
            if self.A is not None:
                A = np.matrix(self.A)
                b = CyLPArray(self.b)
            elif numVars <= 2 and GRUMPY_INSTALLED:
                p = Polyhedron2D(points=points, rays=rays)
                A = np.matrix(p.hrep.A)
                b = np.matrix(p.hrep.b)
            else:
                raise "Must specify problem in inequality form with more than two variables\n"

            #Warning: At the moment, you must put bound constraints in explicitly for split cuts
            x_l = CyLPArray([0 for _ in range(numVars)])

            x = lp.addVariable('x', numVars)

            lp += x >= x_l
            if x_u is not None:
                lp += x <= x_u
            lp += (A * x <= b if self.sense == '<=' else A * x >= b)
            c = CyLPArray(self.c)
            if min_or_max == 'Max':
                lp.objective = -c * x
            else:
                lp.objective = c * x
            self.lp = lp
            self.x = x
Exemple #4
0
 def separate(self, output=False, p=None):
     self.output = output
     while True:
         print 'Iteration ', self.iter
         if self.generate_xtreme_point() >= 1 - EPS:
             break
         self.add_inequality()
         if self.output:
             print "Separation problem solution status:", LpStatus[
                 self.sepProb.solve()]
             for v in self.var:
                 if self.pi[v].value() is not None:
                     print self.pi[v].name + '\t\t', self.pi[v].value()
                 else:
                     print self.pi[v].name + '\t\t', 0
         self.piPrevious = deepcopy(self.piCurrent)
         for v in self.var:
             if self.pi[v].value() is not None:
                 self.piCurrent[v] = self.pi[v].value()
             else:
                 self.piCurrent[v] = 0
         self.iter += 1
         if p is not None:
             self.f.initialize()
             self.f.add_polyhedron(p, label='Polyhedron P')
             xList = (self.x0.values()[0], self.x0.values()[1])
             if len(self.extremePoints) > 2:
                 pp = Polyhedron2D(points=self.extremePoints)
                 self.f.add_polyhedron(
                     pp,
                     color='red',
                     linestyle='dashed',
                     label='Convex Hull of Generated Points')
             elif len(self.extremePoints) == 1:
                 self.f.add_point(self.extremePoints[0],
                                  radius=0.05,
                                  color='green')
                 self.f.add_text([
                     self.extremePoints[0][0] - 0.5,
                     self.extremePoints[0][1] - 0.08
                 ], '$x^0$')
             else:
                 self.f.add_line_segment(
                     self.extremePoints[0],
                     self.extremePoints[1],
                     color='red',
                     linestyle='dashed',
                     label='Convex Hull of Generated Points')
             self.f.set_xlim(p.xlim)
             self.f.set_ylim(p.ylim)
             self.f.add_point(xList, radius=0.05, color='red')
             self.f.add_text([xList[0] - 0.5, xList[1] - 0.08], '$x^*$')
             dList = (self.piCurrent.values()[0],
                      self.piCurrent.values()[1])
             self.f.add_line(dList,
                             1,
                             p.xlim,
                             p.ylim,
                             color='green',
                             linestyle='dashed',
                             label='Separating Hyperplane')
             self.f.show()
         if self.output:
             print self.sepProb.objective.value()
Exemple #5
0
        x.append(LpVariable('x_' + str(i), 0, None, LpInteger))
    # add obj function
    prob += lpSum(mip.c[i] * x[i] for i in range(len(mip.A[0])))
    # add constraints to the prob
    for i in range(len(mip.A)):
        prob += mip.A[i][0] * x[0] + mip.A[i][1] * x[1] <= mip.b[i]
    return prob, x, mip


if __name__ == '__main__':

    display = True
    prob, vars, mip = read_instance(module_name='MIP8')

    if display:
        p = Polyhedron2D(A=mip.A, b=mip.b)
        f = Figure()
        f.add_polyhedron(p, show_int_points=True, label='Polyhedron P')
        f.set_xlim(p.xlim)
        f.set_ylim(p.ylim)
        f.add_point(mip.x_sep, radius=0.05, color='red')
        f.add_text([mip.x_sep[0] - 0.5, mip.x_sep[1] - 0.08], '$x^*$')
        f.show()

    # This is the point to be separated
    x0 = {}
    for index, value in enumerate(mip.x_sep):
        x0[vars[index].name] = value
    i = 0
    ic = GenericSeparation(prob, x0, {'x_0': -1, 'x_1': 0})
    ic.separate(output=True, p=p)
Exemple #6
0
from src.grumpy.polyhedron2D import Polyhedron2D, add_line, add_point

if __name__ == '__main__':
    #points = np.random.random ((20,2))
    #p = make_hull(points)
    A = [[-5, -3], [-5, 5], [1, -2]]

    b = [-10, 1, 2]

    points = [[1.175, 1.375], [2, 0], [2.175, 2.375], [3, 1], [3.175, 2.375],
              [4, 1]]

    fig = plt.figure()
    ax = fig.add_subplot(111)
    ax.grid()
    p = Polyhedron2D(A=A, b=b)
    q = Polyhedron2D(points=points)
    p.draw(ax, color='blue', linestyle='solid', label='$P$')
    q.draw(ax,
           color='black',
           linestyle='solid',
           color_int_points=True,
           label='$Q$')
    ax.set_xlim(p.plot_min[0] - 0.5, p.plot_max[0] + 1)
    ax.set_ylim(p.plot_min[1], p.plot_max[1] + 1)
    pI = p.make_integer_hull()
    pI.draw(ax, color='red', linestyle='dashed', label='conv(S)')
    plt.text(-0.2, 1.3, r'$e_1 = (1.175, 1.375)$')
    plt.text(1.8, -0.2, r'$e_2 = (2, 0)$')
    plt.text(1.5, 2.5, r'$r_1 = (1, 1)$')
    plt.text(3.5, 0.5, r'$r_2 = (2, 1)$')
    if c is not None and obj_val is not None:
        f.add_line(c,
                   obj_val,
                   p.xlim + [0.2, 0.8],
                   p.ylim + [0.2, 1.8],
                   linestyle='dashed',
                   color='black',
                   label="Objective Function")
    if opt is not None:
        f.add_point(opt, 0.04, 'red')
        f.add_text(loc, r'$x^* = %s$' % str(opt))
    f.show()


try:
    p = Polyhedron2D(A=LP.A, b=LP.b)
except AttributeError:
    try:
        p = Polyhedron2D(points=LP.points, rays=LP.rays)
    except AttributeError:
        print 'Error: Must specify either A and b or points and rays'
        p = None

if p is not None:

    if CYLP_INSTALLED:
        lp = CyClpSimplex()

        A = np.matrix(p.hrep.A)
        b = CyLPArray(p.hrep.b)