Beispiel #1
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def test_scripts():
    """Test scripts."""
    from pyvpsolver import VPSolver, VBP, MVP, AFG, LP, MPS
    VPSolver.clear()
    vbp = VBP(W=(1, ), w=[(1, )], b=[1], verbose=True)
    mvp = MVP(Ws=[(1, )], Cs=[1], Qs=[inf], ws=[[(1, )]], b=[1], verbose=True)
    for instance in [vbp, mvp]:
        afg = AFG(instance, verbose=True)
        lp = LP(afg, verbose=True)
        mps = MPS(afg, verbose=True)
        VPSolver.set_verbose(False)
        output, solution = VPSolver.script("vpsolver_glpk.sh",
                                           instance,
                                           options="--seed 1234")
        assert solution[0] == 1
        if isinstance(instance, (VBP, MVP)):
            instance_file = instance.filename
        output, solution = VPSolver.script("vpsolver_glpk.sh", instance_file)
        assert solution[0] == 1
        output, solution = VPSolver.script("vpsolver_glpk.sh", afg)
        assert solution[0] == 1
        output, solution = VPSolver.script("vpsolver_glpk.sh", afg, lp)
        assert solution[0] == 1
        output, solution = VPSolver.script("vpsolver_glpk.sh", afg, mps)
        assert solution[0] == 1
        output, solution = VPSolver.script("vpsolver_glpk.sh", lp)
        assert solution is None
        output, solution = VPSolver.script("vpsolver_glpk.sh", mps)
        assert solution is None
        output, solution = VPSolver.script("vpsolver_glpk.sh", afg.filename)
        assert solution[0] == 1
        output, solution = VPSolver.script("vpsolver_glpk.sh", lp.filename)
        assert solution is None
        output, solution = VPSolver.script("vpsolver_glpk.sh", mps.filename)
        assert solution is None
Beispiel #2
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def main():
    """Examples: how to use VBP, AFG, MPS, LP and VPSolver"""

    # Create instanceA:
    instanceA = VBP([5180], [1120, 1250, 520, 1066, 1000, 1150],
                            [9, 5, 91, 18, 11, 64], verbose=False)

    # Create instanceB from a .vbp file
    instanceB = VBP.from_file("instance.vbp", verbose=False)

    # Create an arc-flow graph for instanceA
    afg = AFG(instanceA, verbose=False)

    # Create .mps and .lp models for instanceA
    mps_model = MPS(afg, verbose=False)
    lp_model = LP(afg, verbose=False)

    # Draw the arc-flow graph for instanceA (requires pygraphviz)
    try:
        afg.graph().draw("tmp/graph.svg")
    except Exception as e:
        print repr(e)

    # Solve instanceA using bin/vpsolver (requires Gurobi)
    try:
        out, sol = VPSolver.vpsolver(instanceA, verbose=True)
    except Exception as e:
        print "Failed to call vpsolver"
        print repr(e)

    # Solve instanceA using any vpsolver script (i.e., any MIP solver):
    #   The scripts accept models with and without the underlying graphs.
    #   However, the graphs are required to extract the solution.
    out, sol = VPSolver.script("vpsolver_glpk.sh", lp_model, afg, verbose=True)
    try:
        out, sol = VPSolver.script(
            "vpsolver_gurobi.sh", mps_model, verbose=True
        )
    except Exception as e:
        print repr(e)

    # Solve an instance directly without creating AFG, MPS or LP objects:
    out, sol = VPSolver.script("vpsolver_glpk.sh", instanceB, verbose=True)

    # Print the solution:
    obj, patterns = sol
    print "Objective:", obj
    print "Solution:", patterns

    # Pretty-print the solution:
    vbpsolver.print_solution(obj, patterns)

    assert obj == 21  # check the solution objective value
Beispiel #3
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def solve_worker(app_name, method, form, args, output=sys.stdout):
    """Worker for solving the problem in a separate process."""
    VPSolver.PLIST = []

    def signal_handler(sig, frame):
        """Signal handler for cleaner exit."""
        for p in VPSolver.PLIST:
            try:
                os.killpg(p.pid, signal.SIGTERM)
            except Exception as e:
                pass
        sys.exit(0)

    signal.signal(signal.SIGTERM, signal_handler)

    sys.stdout = output
    sys.stderr = output
    input_ = form["input"].strip("\n")
    if DEBUG:
        print("Input:\n{0}\n\nOutput:".format(input_))
        output.flush()

    if app_name == "vbp":
        tmpfile = VPSolver.new_tmp_file(ext=".vbp")
        with open(tmpfile, "w") as f:
            f.write(input_)
        instance = VBP.from_file(tmpfile, verbose=False)
        afg = AFG(instance, verbose=True)
        lp_model = LP(afg, verbose=False)
        out, sol = VPSolver.script(form["script"],
                                   lp_model,
                                   afg,
                                   pyout=False,
                                   verbose=True)
    elif app_name == "mvp":
        tmpfile = VPSolver.new_tmp_file(ext=".mvp")
        with open(tmpfile, "w") as f:
            f.write(input_)
        instance = MVP.from_file(tmpfile, verbose=False)
        afg = AFG(instance, verbose=True)
        lp_model = LP(afg, verbose=False)
        out, sol = VPSolver.script(form["script"],
                                   lp_model,
                                   afg,
                                   pyout=False,
                                   verbose=True)

    print("EOF\n")
    output.flush()
Beispiel #4
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def solve_worker(app_name, method, form, args, output=sys.stdout):
    """Worker for solving the problem in a separate process."""
    VPSolver.PLIST = []

    def signal_handler(sig, frame):
        """Signal handler for cleaner exit."""
        for p in VPSolver.PLIST:
            try:
                os.killpg(p.pid, signal.SIGTERM)
            except Exception as e:
                pass
        sys.exit(0)
    signal.signal(signal.SIGTERM, signal_handler)

    sys.stdout = output
    sys.stderr = output
    input_ = form["input"].strip("\n")
    if DEBUG:
        print("Input:\n{0}\n\nOutput:".format(input_))
        output.flush()

    if app_name == "vbp":
        tmpfile = VPSolver.new_tmp_file(ext=".vbp")
        with open(tmpfile, "w") as f:
            f.write(input_)
        instance = VBP.from_file(tmpfile, verbose=False)
        afg = AFG(instance, verbose=True)
        lp_model = LP(afg, verbose=False)
        out, sol = VPSolver.script(
            form["script"], lp_model, afg,
            verbose=True
        )
    elif app_name == "pympl":
        tmpfile = VPSolver.new_tmp_file(ext=".mod")
        parser = PyMPL()
        parser.input = input_
        parser.parse()
        parser.write(tmpfile)
        VPSolver.run(
            "glpsol --math {0}".format(tmpfile),
            grepv="Generating",
            verbose=True
        )

    print("EOF\n")
    output.flush()
Beispiel #5
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def test_lowlevel():
    """Test low-level API."""
    from pyvpsolver import VPSolver, VBP, MVP, AFG
    vbp = VBP(W=(1, ), w=[(1, )], b=[1])
    mvp = MVP(Ws=[(1, )], Cs=[1], Qs=[inf], ws=[[(1, )]], b=[1])
    afg_file = VPSolver.new_tmp_file(".afg")
    lp_file = VPSolver.new_tmp_file(".lp")
    mps_file = VPSolver.new_tmp_file(".mps")
    svg_file = VPSolver.new_tmp_file(".svg")
    VPSolver.vbp2afg(vbp, afg_file)
    VPSolver.vbp2afg(mvp, afg_file)
    VPSolver.vbp2afg(vbp.filename, afg_file)
    VPSolver.vbp2afg(mvp.filename, afg_file)
    VPSolver.afg2lp(afg_file, lp_file)
    VPSolver.afg2mps(afg_file, mps_file)
    VPSolver.afg2lp(AFG(vbp), lp_file)
    VPSolver.afg2mps(AFG(mvp), mps_file)
Beispiel #6
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def test_vbpsol():
    """Test vbpsol."""
    from pyvpsolver import VPSolver, VBP, MVP, AFG, LP, MPS
    vbp = VBP(W=(1, ), w=[(1, )], b=[1], verbose=True)
    afg = AFG(vbp, verbose=True)
    lp = LP(afg, verbose=True)
    sol_file = VPSolver.new_tmp_file(".sol")
    output, solution = VPSolver.script_wsol("vpsolver_glpk.sh", lp)
    assert isinstance(solution, dict)
    with open(sol_file, "w") as f:
        lst = []
        for var, value in solution.items():
            lst.append(str(var))
            lst.append(str(value))
        print(" ".join(lst), file=f)
    obj, patterns = VPSolver.vbpsol(afg, sol_file)
    assert obj == 1
Beispiel #7
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 def _generate_graph(self, W, w, labels, bounds, binary, S, T, LOSS):
     """Generate an arc-flow graph."""
     from pyvpsolver import VBP, AFG
     m = len(w)
     ndims = len(W)
     if bounds is not None:
         b = bounds
     else:
         b = [
             min(W[d] // w[i][d]) for d in range(ndims) if w[i][d] != 0
             for i in range(m)
         ]
     instance = VBP(W, w, b, binary=binary, verbose=False)
     graph = AFG(instance, verbose=Tools.VERBOSE).graph()
     graph.relabel(
         lambda u: S if u == graph.S else T
         if u == graph.Ts[0] else str(u), lambda lbl: labels[lbl]
         if lbl != graph.LOSS else LOSS)
     return graph
Beispiel #8
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def test_draw():
    """Test scripts."""
    from pyvpsolver import VPSolver, VBP, MVP, AFG
    vbp = VBP(W=(1, ), w=[(1, )], b=[1])
    mvp = MVP(Ws=[(1, )], Cs=[1], Qs=[inf], ws=[[(1, )]], b=[1])
    svg_file = VPSolver.new_tmp_file(".svg")
    for instance in [vbp, mvp]:
        afg = AFG(instance)
        try:
            afg.draw(svg_file, lpaths=True, graph_attrs={"size": "8,8"})
        except Exception as e:
            print(repr(e))
        try:
            VPSolver.afg2svg(afg, svg_file)
        except Exception as e:
            print(repr(e))
        try:
            VPSolver.afg2svg(afg.filename, svg_file)
        except Exception as e:
            print(repr(e))
Beispiel #9
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    def _generate_model(self,
                        zvar,
                        W,
                        w,
                        b,
                        bounds=None,
                        binary=False,
                        labels=None,
                        prefix=""):
        """Generate an arc-flow model."""
        from pyvpsolver import VBP, AFG
        m = len(w)
        bb = [0] * m
        bvars = []
        for i in range(m):
            if isinstance(b[i], six.string_types):
                bb[i] = min(W[d] // w[i][d] for d in range(len(w[i]))
                            if w[i][d] != 0)
                if bounds is not None:
                    bb[i] = min(bb[i], bounds[i])
                bvars.append(b[i])
            else:
                bb[i] = b[i]

        instance = VBP(W, w, bb, binary=binary, verbose=False)
        graph = AFG(instance, verbose=Tools.VERBOSE).graph()
        feedback = (graph.Ts[0], graph.S, graph.LOSS)

        vnames = {}
        vnames[feedback] = zvar
        ub = {}
        varl, cons = graph.get_flow_cons(vnames)
        assocs = graph.get_assocs(vnames)
        graph.names = vnames

        if labels is None:
            labels = {i: "i={0}".format(i + 1) for i in instance.labels}
            for i in range(m):
                if isinstance(b[i], six.string_types):
                    labels[i] = b[i]
        elif isinstance(labels, list):
            labels = dict(enumerate(labels))
        graph.set_labels({(u, v, i): [labels[i]]
                          for (u, v, i) in graph.A if i in labels})

        for i in range(m):
            if i not in assocs:
                assocs[i] = []
            if bounds is not None:
                for var in assocs[i]:
                    ub[var] = bounds[i]
            if isinstance(b[i], six.string_types):
                varl.append(b[i])
                cons.append((assocs[i], "=", b[i]))
            else:
                if b[i] > 1:
                    cons.append((assocs[i], ">=", b[i]))
                else:
                    cons.append((assocs[i], "=", b[i]))

        model = Model()
        for var in varl:
            model.add_var(name=var, lb=0, ub=ub.get(var, None), vtype="I")
        for lincomb, sign, rhs in cons:
            model.add_con(lincomb, sign, rhs)

        model.add_var(name="_total_flow", vtype="I")
        model.add_con("_total_flow", "=", zvar)

        declared_vars = set(bvars)

        def var_name(name):
            if name == zvar:
                return name
            elif name in declared_vars:
                return name
            else:
                return prefix + name

        def con_name(name):
            return prefix + name

        model.rename_vars(var_name)
        model.rename_cons(con_name)

        return graph, model, declared_vars
Beispiel #10
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def main():
    """Examples: how to use VBP, MVP, AFG, MPS, LP and VPSolver"""
    from pyvpsolver import VPSolver, VBP, MVP, AFG, MPS, LP
    from pyvpsolver.solvers import vbpsolver, mvpsolver
    os.chdir(os.path.dirname(__file__) or os.curdir)

    # Create instanceA:
    instanceA = VBP(
        (5180,),
        [(1120,), (1250,), (520,), (1066,), (1000,), (1150,)],
        [9, 5, 91, 18, 11, 64]
    )

    # Create instanceB from a .vbp file
    instanceB = VBP.from_file("instance.vbp")

    # Create an arc-flow graph for instanceA
    afg = AFG(instanceA, verbose=False)

    # Create .mps and .lp models for instanceA
    mps_model = MPS(afg, verbose=False)
    lp_model = LP(afg, verbose=False)

    # Draw the arc-flow graph for instanceA (requires pygraphviz)
    try:
        afg.draw("tmp/graph1.svg")
    except ImportError as e:
        print(repr(e))

    # Solve instanceA using bin/vpsolver (requires Gurobi)
    try:
        out, sol = VPSolver.vpsolver(instanceA, verbose=True)
    except Exception as e:
        print("Failed to call vpsolver")
        print(repr(e))

    # Solve instanceA using any vpsolver script (i.e., any MIP solver):
    #   The scripts accept models with and without the underlying graphs.
    #   However, the graphs are required to extract the solution.
    out, sol = VPSolver.script("vpsolver_glpk.sh", lp_model, afg, verbose=True)
    try:
        out, sol = VPSolver.script(
            "vpsolver_gurobi.sh", mps_model, verbose=True
        )
    except Exception as e:
        print(repr(e))

    # Solve an instance directly without creating AFG, MPS or LP objects:
    out, solution = VPSolver.script(
        "vpsolver_glpk.sh", instanceB, verbose=True
    )

    # Print the solution:
    obj, patterns = solution
    print("Objective:", obj)
    print("Solution:", patterns)

    # Pretty-print the solution:
    vbpsolver.print_solution(solution)

    # check the solution objective value
    obj, patterns = solution
    assert obj == 21

    # Create instanceC:
    W1 = (100, 100)
    W2 = (50, 120)
    W3 = (150, 25)
    ws1, b1 = [(50, 25), (25, 50), (0, 75)], 1
    ws2, b2 = [(40, 40), (60, 25), (25, 60)], 1
    ws3, b3 = [(30, 10), (20, 40), (10, 50)], 1
    Ws = [W1, W2, W3]     # capacities
    Cs = [3, 7, 2]        # costs
    Qs = [-1, -1, -1]     # number of bins available
    ws = [ws1, ws2, ws3]  # items
    b = [b1, b2, b3]      # demands
    instanceC = MVP(Ws, Cs, Qs, ws, b)

    # Solve an instance directly without creating AFG, MPS or LP objects:
    out, solution = VPSolver.script(
        "vpsolver_glpk.sh", instanceC, verbose=True
    )
    mvpsolver.print_solution(solution)

    # check the solution objective value
    obj, patterns = solution
    assert obj == 3

    # Create instanceD from a .mvp file
    instanceD = MVP.from_file("instance.mvp")

    # Draw the arc-flow graph for instanceD (requires pygraphviz)
    try:
        AFG(instanceD).draw("tmp/graph2.svg")
    except ImportError as e:
        print(repr(e))

    # Solve an instance directly without creating AFG, MPS or LP objects:
    out, solution = VPSolver.script(
        "vpsolver_glpk.sh", instanceD, verbose=True
    )
    mvpsolver.print_solution(solution)

    # check the solution objective value
    obj, patterns = solution
    assert obj == 8
Beispiel #11
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def main():
    """Examples: how to use VBP, MVP, AFG, MPS, LP and VPSolver"""
    from pyvpsolver import VPSolver, VBP, MVP, AFG, MPS, LP
    from pyvpsolver.solvers import vbpsolver, mvpsolver
    os.chdir(os.path.dirname(__file__) or os.curdir)

    # Create instanceA:
    instanceA = VBP((5180, ), [(1120, ), (1250, ), (520, ), (1066, ), (1000, ),
                               (1150, )], [9, 5, 91, 18, 11, 64])

    # Create instanceB from a .vbp file
    instanceB = VBP.from_file("instance.vbp")

    # Create an arc-flow graph for instanceA
    afg = AFG(instanceA, verbose=False)

    # Create .mps and .lp models for instanceA
    mps_model = MPS(afg, verbose=False)
    lp_model = LP(afg, verbose=False)

    # Draw the arc-flow graph for instanceA (requires pygraphviz)
    try:
        afg.draw("tmp/graph1.svg")
    except ImportError as e:
        print(repr(e))

    # Solve instanceA using bin/vpsolver (requires Gurobi)
    try:
        out, sol = VPSolver.vpsolver(instanceA, verbose=True)
    except Exception as e:
        print("Failed to call vpsolver")
        print(repr(e))

    # Solve instanceA using any vpsolver script (i.e., any MIP solver):
    #   The scripts accept models with and without the underlying graphs.
    #   However, the graphs are required to extract the solution.
    out, sol = VPSolver.script("vpsolver_glpk.sh", lp_model, afg, verbose=True)
    try:
        out, sol = VPSolver.script("vpsolver_gurobi.sh",
                                   mps_model,
                                   verbose=True)
    except Exception as e:
        print(repr(e))

    # Solve an instance directly without creating AFG, MPS or LP objects:
    out, solution = VPSolver.script("vpsolver_glpk.sh",
                                    instanceB,
                                    verbose=True)

    # Print the solution:
    obj, patterns = solution
    print("Objective:", obj)
    print("Solution:", patterns)

    # Pretty-print the solution:
    vbpsolver.print_solution(solution)

    # check the solution objective value
    obj, patterns = solution
    assert obj == 21

    # Create instanceC:
    W1 = (100, 100)
    W2 = (50, 120)
    W3 = (150, 25)
    ws1, b1 = [(50, 25), (25, 50), (0, 75)], 1
    ws2, b2 = [(40, 40), (60, 25), (25, 60)], 1
    ws3, b3 = [(30, 10), (20, 40), (10, 50)], 1
    Ws = [W1, W2, W3]  # capacities
    Cs = [3, 7, 2]  # costs
    Qs = [-1, -1, -1]  # number of bins available
    ws = [ws1, ws2, ws3]  # items
    b = [b1, b2, b3]  # demands
    instanceC = MVP(Ws, Cs, Qs, ws, b)

    # Solve an instance directly without creating AFG, MPS or LP objects:
    out, solution = VPSolver.script("vpsolver_glpk.sh",
                                    instanceC,
                                    verbose=True)
    mvpsolver.print_solution(solution)

    # check the solution objective value
    obj, patterns = solution
    assert obj == 3

    # Create instanceD from a .mvp file
    instanceD = MVP.from_file("instance.mvp")

    # Draw the arc-flow graph for instanceD (requires pygraphviz)
    try:
        AFG(instanceD).draw("tmp/graph2.svg")
    except ImportError as e:
        print(repr(e))

    # Solve an instance directly without creating AFG, MPS or LP objects:
    out, solution = VPSolver.script("vpsolver_glpk.sh",
                                    instanceD,
                                    verbose=True)
    mvpsolver.print_solution(solution)

    # check the solution objective value
    obj, patterns = solution
    assert obj == 8