Beispiel #1
0
def main():
    if len(sys.argv) != 11:
        print(
            "Input parameters must be: 'lambda mu theta C c0 Q L H simulation_time repeats'"
        )
    else:
        start_time = time.time()

        lambd = float(sys.argv[1])
        mu = float(sys.argv[2])
        theta = float(sys.argv[3])
        C = int(sys.argv[4])
        c0 = int(sys.argv[5])
        Q = int(sys.argv[6])
        L = int(sys.argv[7])
        H = int(sys.argv[8])
        simulation_time = int(sys.argv[9])
        repeats = int(sys.argv[10])

        print("Test for M/M/C[c0]/R[L,H]: lambda =", lambd, ", mu =", mu,
              ", theta = ", theta, ", C =", C, ", c0=", c0, ", Q =", Q,
              ", sim time =", simulation_time, ", repeats =", repeats)

        B = 0
        W = 0
        N = 0

        is_debug = False
        simulation = Simulation("m/m/c[c0]/r[l,h]", lambd, mu, theta, C, c0, L,
                                H, simulation_time, Q, is_debug)
        for i in range(0, repeats):
            simulation = Simulation("m/m/c[c0]/r[l,h]", lambd, mu, theta, C,
                                    c0, L, H, simulation_time, Q, is_debug)
            simulation.start_requests(simulation_time)
            B += simulation.queue.blocked / (simulation.queue.blocked +
                                             simulation.served_count)

            w = 0
            for request in simulation.served_requests:
                w += request.w
            for request in simulation.queue.blocked_requests:
                w += request.w
            W += w / (simulation.served_count +
                      len(simulation.queue.blocked_requests))
            N += (w / (simulation.served_count +
                       len(simulation.queue.blocked_requests))) * lambd

        B /= repeats
        W /= repeats
        N /= repeats

        end_time = time.time()

        print("B =", B, "\nW =", W, "\nN =", N)
        print("Execution time = %s seconds" % (end_time - start_time))
Beispiel #2
0
    def generate_statistics(self):
        generated_values = []

        t1 = time.time()
        for lambd in self.range_dict[PARAM.LAMBDA]:
            for mu in self.range_dict[PARAM.MU]:
                for theta in self.range_dict[PARAM.THETA]:
                    for C in self.range_dict[PARAM.C]:
                        for c0 in self.range_dict[PARAM.c0]:
                            for L in self.range_dict[PARAM.L]:
                                for H in self.range_dict[PARAM.H]:
                                    for Q in self.range_dict[PARAM.Q]:
                                        if lambd <= 0: continue
                                        if mu <= 0: continue
                                        if theta <= 0: continue
                                        if C <= 0: continue
                                        if c0 <= 0: continue
                                        if L <= 0: continue
                                        if H <= 0: continue
                                        if Q <= 0: continue
                                        if c0 > C or c0 < 0: continue
                                        if H - L < 2: continue
                                        if Q - H <= 2: continue
                                        if H < L or H > Q: continue
                                        if L > Q: continue

                                        start_time = time.time()
                                        generated_values_storage = Generated_values_storage(
                                        )
                                        for repeats in self.range_dict[
                                                PARAM.REPEATS]:
                                            sim = Simulation(
                                                self.mode, lambd, mu, theta, C,
                                                c0, L, H, self.simulation_time,
                                                Q, self.is_debug)
                                            if (self.strategy == "time"):
                                                sim.start()
                                            else:
                                                sim.start_requests(
                                                    self.simulation_time)
                                            generated_values_storage.add(sim)
                                        end_time = time.time()
                                        generated_values_storage.normalize(
                                            self.parameters[
                                                PARAM.REPEATS].end_value)
                                        generated_values.append(
                                            generated_values_storage)
                                        self.log(lambd, mu, theta, C, c0, L, H,
                                                 Q, start_time, end_time)
        t2 = time.time()
        print("Total simulation time = %.5f" % (t2 - t1))
        return generated_values
def main():
    if len(sys.argv) != 11:
        print("Input parameters must be: 'lambda mu theta C c0 Q L H simulation_time repeats'")
    else:
        start_time = time.time()

        lambd = float(sys.argv[1])
        mu = float(sys.argv[2])
        theta = float(sys.argv[3])
        C = int(sys.argv[4])
        c0 = int(sys.argv[5])
        Q = int(sys.argv[6])
        L = int(sys.argv[7])
        H = int(sys.argv[8])
        simulation_time = int(sys.argv[9])
        repeats = int(sys.argv[10])

        print("Difference test for M/M/C[c0]/R: lambda =", lambd, ", mu =", mu, ", C =", C, ", c0=", c0,", Q =", Q, ", theta = ", theta, ", sim time =",
                  simulation_time, ", repeats =", repeats)
        print("c0 will be used for theoretical m/m/c/r calculation")

        ### theoretical
        theoretical_mmcr = MMCR(lambd, mu, c0, Q)
        theoretical_result = theoretical_mmcr.run()

        B = theoretical_result[0]
        W = theoretical_result[1]
        N = theoretical_result[2]

        ### sim
        B2 = 0
        W2 = 0
        N2 = 0

        is_debug = False
        if is_debug: print("Q=",Q)
        simulation = Simulation("m/m/c[c0]/r", lambd, mu, theta, C, c0, L, H, simulation_time, Q, is_debug)
        for i in range(0, repeats):
            simulation = Simulation("m/m/c[c0]/r", lambd, mu, theta, C, c0, L, H, simulation_time, Q, is_debug)
            simulation.start_requests(10000)
            B2 += simulation.queue.blocked / (simulation.queue.blocked + simulation.served_count)

            w = 0
            for request in simulation.served_requests:
                w += request.w
            for request in simulation.queue.blocked_requests:
                w += request.w
            W2 += w / (simulation.served_count + len(simulation.queue.blocked_requests))
            N2 += (w / (simulation.served_count + len(simulation.queue.blocked_requests))) * lambd

        B2 /= repeats
        W2 /= repeats
        N2 /= repeats

        end_time = time.time()

        print("theoretical B =", B, ", simulation B=", B2, ", Difference = ", abs((B2 - B) / B),
                  "\ntheoretical W =", W, ", simulation W=", W2, ", Difference = ", abs((W2 - W) / W),
                  "\ntheoretical N =", N, ", simulation N=", N2, ", Difference = ", abs((N2 - N) / N))

        print("Execution time = %s seconds" % (end_time - start_time))