Beispiel #1
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    def testBOHB(self):
        from ray.tune.suggest.bohb import TuneBOHB

        searcher = TuneBOHB(space=self.config, metric=self.metric_name, mode="max")

        self._save(searcher)

        searcher = TuneBOHB(space=self.config, metric=self.metric_name, mode="max")
        self._restore(searcher)
Beispiel #2
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def tunerTrain():
    ray.init(_memory=4000000000, num_cpus=5)
    searchSpace = {
        'lr': tune.loguniform(1e-4, 9e-1),
        'finalOutput':
        tune.uniform(2, 50),  # minimum of 2, other 1//2 = 0 activation maps
        'stride1': tune.uniform(1, 4),
        'stride2': tune.uniform(1, 4),
        'batchSize': tune.uniform(2, 32),
        'finalChannel': tune.uniform(1, 50),
    }

    # analysis = tune.run(train, num_samples=1, scheduler=ASHAScheduler(metric='score', mode='max'),
    #                     config=searchSpace)

    algo = TuneBOHB(max_concurrent=4, metric="mean_loss", mode="max")
    bohb = HyperBandForBOHB(
        metric="mean_loss",
        mode="max",
    )
    analysis = tune.run(train,
                        config=searchSpace,
                        scheduler=bohb,
                        search_alg=algo,
                        num_samples=10)
    # bayesopt = BayesOptSearch( metric="mean_loss", mode="max", random_search_steps = 3)

    # tune.run(train, search_alg=bayesopt, config= searchSpace, scheduler=ASHAScheduler("mean_loss","max"))
    print("Best config: ",
          analysis.get_best_config(metric="mean_loss", mode="max"))
 def _get_search_algorithm(
     self, search_algorithm, config_space, metric, mode, max_concurrent):
     if search_algorithm == "BO":
         algo = BayesOptSearch(
             utility_kwargs={
             "kind": "ucb",
             "kappa": 2.5,
             "xi": 0.0
         })
         algo = ConcurrencyLimiter(algo, max_concurrent=max_concurrent)
         scheduler = AsyncHyperBandScheduler()
     elif search_algorithm == "BOHB":
         experiment_metrics = dict(metric=metric, mode=mode)
         algo = TuneBOHB(
             config_space, max_concurrent=max_concurrent, **experiment_metrics)
         scheduler = HyperBandForBOHB(
             time_attr="training_iteration",
             reduction_factor=4)
     elif search_algorithm == "PBT":
         # Problem of PBT: It mutates the param value, so sometimes, it generates unacceptable values
         algo = None
         scheduler = PopulationBasedTraining(
             time_attr='training_iteration',
             perturbation_interval=2,  # Every N time_attr units, "perturb" the parameters.
             hyperparam_mutations=config_space)
     elif search_algorithm == "GRID" or search_algorithm == "RANDOM":
         algo = None
         scheduler = None
     else:
         raise Exception(search_algorithm, "is not available yet")
     return algo, scheduler
Beispiel #4
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    def testBOHB(self):
        from ray.tune.suggest.bohb import TuneBOHB

        converted_config = TuneBOHB.convert_search_space(self.config)
        converted_config.seed(1000)  # At least one nan, inf, -inf and float

        out = tune.run(_invalid_objective,
                       search_alg=TuneBOHB(space=converted_config,
                                           metric="_metric",
                                           mode="max"),
                       metric="_metric",
                       mode="max",
                       num_samples=8,
                       reuse_actors=False)

        best_trial = out.best_trial
        self.assertLessEqual(best_trial.config["report"], 2.0)
Beispiel #5
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def main(args):
    cfg = setup(args)

    search_space = CS.ConfigurationSpace()
    search_space.add_hyperparameters([
        CS.UniformFloatHyperparameter(name="lr", lower=1e-6, upper=1e-3),
        CS.UniformFloatHyperparameter(name="wd", lower=0, upper=1e-3),
        CS.UniformFloatHyperparameter(name="wd_bias", lower=0, upper=1e-3),
        CS.CategoricalHyperparameter(name="bsz",
                                     choices=[64, 96, 128, 160, 224, 256]),
        CS.CategoricalHyperparameter(name="num_inst",
                                     choices=[2, 4, 8, 16, 32]),
        CS.UniformIntegerHyperparameter(name="delay_iters", lower=20,
                                        upper=60),
        CS.UniformFloatHyperparameter(name="ce_scale", lower=0.1, upper=1.0),
        CS.UniformIntegerHyperparameter(name="circle_scale",
                                        lower=8,
                                        upper=256),
        CS.UniformFloatHyperparameter(name="circle_margin",
                                      lower=0.1,
                                      upper=0.5),
        CS.CategoricalHyperparameter(name="autoaug_enabled",
                                     choices=[True, False]),
        CS.CategoricalHyperparameter(name="cj_enabled", choices=[True, False]),
    ])

    exp_metrics = dict(metric="score", mode="max")
    bohb_hyperband = HyperBandForBOHB(
        time_attr="training_iteration",
        max_t=7,
        **exp_metrics,
    )
    bohb_search = TuneBOHB(search_space, max_concurrent=4, **exp_metrics)

    reporter = CLIReporter(parameter_columns=["bsz", "num_inst", "lr"],
                           metric_columns=["r1", "map", "training_iteration"])

    analysis = tune.run(partial(train_reid_tune, cfg),
                        resources_per_trial={
                            "cpu": 10,
                            "gpu": 1
                        },
                        search_alg=bohb_search,
                        num_samples=args.num_samples,
                        scheduler=bohb_hyperband,
                        progress_reporter=reporter,
                        local_dir=cfg.OUTPUT_DIR,
                        keep_checkpoints_num=4,
                        name="bohb")

    best_trial = analysis.get_best_trial("map", "max", "last")
    logger.info("Best trial config: {}".format(best_trial.config))
    logger.info("Best trial final validation mAP: {}, Rank-1: {}".format(
        best_trial.last_result["map"], best_trial.last_result["r1"]))
Beispiel #6
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    def testBOHB(self):
        from ray.tune.suggest.bohb import TuneBOHB

        out = tune.run(_invalid_objective,
                       search_alg=TuneBOHB(seed=1000),
                       config=self.config,
                       mode="max",
                       num_samples=8,
                       reuse_actors=False)

        best_trial = out.best_trial
        self.assertLessEqual(best_trial.config["report"], 2.0)
Beispiel #7
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    def testConvertBOHB(self):
        from ray.tune.suggest.bohb import TuneBOHB
        import ConfigSpace

        config = {
            "a": tune.sample.Categorical([2, 3, 4]).uniform(),
            "b": {
                "x": tune.sample.Integer(0, 5).quantized(2),
                "y": 4,
                "z": tune.sample.Float(1e-4, 1e-2).loguniform()
            }
        }
        converted_config = TuneBOHB.convert_search_space(config)
        bohb_config = ConfigSpace.ConfigurationSpace()
        bohb_config.add_hyperparameters([
            ConfigSpace.CategoricalHyperparameter("a", [2, 3, 4]),
            ConfigSpace.UniformIntegerHyperparameter("b/x",
                                                     lower=0,
                                                     upper=4,
                                                     q=2),
            ConfigSpace.UniformFloatHyperparameter("b/z",
                                                   lower=1e-4,
                                                   upper=1e-2,
                                                   log=True)
        ])

        converted_config.seed(1234)
        bohb_config.seed(1234)

        searcher1 = TuneBOHB(space=converted_config)
        searcher2 = TuneBOHB(space=bohb_config)

        config1 = searcher1.suggest("0")
        config2 = searcher2.suggest("0")

        self.assertEqual(config1, config2)
        self.assertIn(config1["a"], [2, 3, 4])
        self.assertIn(config1["b"]["x"], list(range(5)))
        self.assertLess(1e-4, config1["b"]["z"])
        self.assertLess(config1["b"]["z"], 1e-2)

        searcher = TuneBOHB(metric="a", mode="max")
        analysis = tune.run(_mock_objective,
                            config=config,
                            search_alg=searcher,
                            num_samples=1)
        trial = analysis.trials[0]
        self.assertIn(trial.config["a"], [2, 3, 4])
        self.assertEqual(trial.config["b"]["y"], 4)
Beispiel #8
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    def set_basic_conf(self):
        space = {
            "width": tune.uniform(0, 20),
            "height": tune.uniform(-100, 100)
        }

        def cost(space, reporter):
            for i in range(10):
                reporter(loss=(space["height"] - 14)**2 -
                         abs(space["width"] - 3 - i))

        search_alg = TuneBOHB(space=space, metric="loss", mode="min", seed=1)

        return search_alg, cost
Beispiel #9
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def setup_tune_scheduler():
    config_space = workload.create_ch()

    experiment_metrics = workload.exp_metric()
    bohb_hyperband = HyperBandForBOHB(time_attr="training_iteration",
                                      max_t=243,
                                      reduction_factor=3,
                                      **experiment_metrics)
    bohb_search = TuneBOHB(config_space, **experiment_metrics)

    return dict(
        scheduler=bohb_hyperband,
        search_alg=bohb_search,
        resources_per_trial=com.detect_baseline_resource(),
    )
def setup_tune_scheduler(num_worker):

    # BOHB uses ConfigSpace for their hyperparameter search space
    config_space = workload.create_ch()

    experiment_metrics = workload.exp_metric()
    bohb_search = TuneBOHB(config_space, **experiment_metrics)

    bohb_hyperband = SyncBOHB(time_attr="training_iteration",
                              max_t=81,
                              reduction_factor=3,
                              **experiment_metrics)

    return dict(
        scheduler=bohb_hyperband,
        search_alg=bohb_search,
        resources_per_trial=com.detect_baseline_resource(),
    )
Beispiel #11
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    #     CS.UniformFloatHyperparameter("width", lower=0, upper=20))
    # config_space.add_hyperparameter(
    #     CS.UniformFloatHyperparameter("height", lower=-100, upper=100))
    # config_space.add_hyperparameter(
    #     CS.CategoricalHyperparameter(
    #         "activation", choices=["relu", "tanh"]))

    bohb_hyperband = HyperBandForBOHB(
        time_attr="training_iteration",
        max_t=100,
        reduction_factor=4,
        stop_last_trials=False,
    )

    bohb_search = TuneBOHB(
        # space=config_space,  # If you want to set the space manually
    )
    bohb_search = tune.suggest.ConcurrencyLimiter(bohb_search, max_concurrent=4)

    analysis = tune.run(
        MyTrainableClass,
        name="bohb_test",
        config=config,
        scheduler=bohb_hyperband,
        search_alg=bohb_search,
        num_samples=10,
        stop={"training_iteration": 100},
        metric="episode_reward_mean",
        mode="max",
    )
                # losses.ACLower(),
                # losses.Motication(),
                # losses.GaussACDC(),
            ],
        ))

    add(cat("max_validation_steps", [100]))
    add(cat("batches_per_step", [10]))


metric = dict(metric="validation_loss", mode="min")
scheduling = HyperBandForBOHB(time_attr="training_iteration",
                              max_t=500,
                              reduction_factor=3,
                              **metric)
search = TuneBOHB(config_space, **metric)

if __name__ == "__main__":
    #sys.exit(10)
    # ray.init(local_mode=True)  # use only one thread to make debugging easier
    analysis = tune.run(
        trainable.MultipackTrainable,
        name="MPT_long_run",
        scheduler=scheduling,
        search_alg=search,
        num_samples=1000,
        stop={"training_iteration": 500},
        max_failures=0,  # for debugging purposes
        resources_per_trial={
            "cpu": CPU_WORKERS_PER_TRAIL,
            "gpu": 1
Beispiel #13
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        ])
        # Feed the score back back to Tune.
        del fx_model
        gc.collect()
        tune.report(total_score=score)

    config = {
        "top_p": tune.uniform(0.80, 0.999),
        "hidden_size": tune.randint(128, 512)
    }

    bohb_hyperband = HyperBandForBOHB(time_attr="training_iteration",
                                      max_t=100,
                                      reduction_factor=2)

    bohb_search = TuneBOHB(max_concurrent=2)

    analysis = tune.run(training_function,
                        name="bohb_test",
                        config=config,
                        scheduler=bohb_hyperband,
                        search_alg=bohb_search,
                        num_samples=12,
                        metric="total_score",
                        mode="max",
                        resources_per_trial={'gpu': 1},
                        callbacks=[CSVLoggerCallback(),
                                   JsonLoggerCallback()])

    print("Best hyperparameters found were: ", analysis.best_config)
Beispiel #14
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def cifar10_main(method="BlendSearch",
                 num_samples=10,
                 max_num_epochs=100,
                 gpus_per_trial=1):
    data_dir = os.path.abspath("test/data")
    load_data(data_dir)  # Download data for all trials before starting the run
    if method == "BlendSearch":
        from flaml import tune
    else:
        from ray import tune
    if method in ["BOHB"]:
        config = {
            "l1": tune.randint(2, 8),
            "l2": tune.randint(2, 8),
            "lr": tune.loguniform(1e-4, 1e-1),
            "num_epochs": tune.qloguniform(1, max_num_epochs, q=1),
            "batch_size": tune.randint(1, 4),
        }
    else:
        config = {
            "l1": tune.randint(2, 9),
            "l2": tune.randint(2, 9),
            "lr": tune.loguniform(1e-4, 1e-1),
            "num_epochs": tune.loguniform(1, max_num_epochs),
            "batch_size": tune.randint(1, 5),
        }
    import ray

    time_budget_s = 600
    np.random.seed(7654321)
    start_time = time.time()
    if method == "BlendSearch":
        result = tune.run(
            ray.tune.with_parameters(train_cifar, data_dir=data_dir),
            config=config,
            metric="loss",
            mode="min",
            low_cost_partial_config={"num_epochs": 1},
            max_resource=max_num_epochs,
            min_resource=1,
            scheduler="asha",
            resources_per_trial={
                "cpu": 1,
                "gpu": gpus_per_trial
            },
            local_dir="logs/",
            num_samples=num_samples,
            time_budget_s=time_budget_s,
            use_ray=True,
        )
    else:
        if "ASHA" == method:
            algo = None
        elif "BOHB" == method:
            from ray.tune.schedulers import HyperBandForBOHB
            from ray.tune.suggest.bohb import TuneBOHB

            algo = TuneBOHB()
            scheduler = HyperBandForBOHB(max_t=max_num_epochs)
        elif "Optuna" == method:
            from ray.tune.suggest.optuna import OptunaSearch

            algo = OptunaSearch(seed=10)
        elif "CFO" == method:
            from flaml import CFO

            algo = CFO(low_cost_partial_config={
                "num_epochs": 1,
            })
        elif "Nevergrad" == method:
            from ray.tune.suggest.nevergrad import NevergradSearch
            import nevergrad as ng

            algo = NevergradSearch(optimizer=ng.optimizers.OnePlusOne)
        if method != "BOHB":
            from ray.tune.schedulers import ASHAScheduler

            scheduler = ASHAScheduler(max_t=max_num_epochs, grace_period=1)
        result = tune.run(
            tune.with_parameters(train_cifar, data_dir=data_dir),
            resources_per_trial={
                "cpu": 1,
                "gpu": gpus_per_trial
            },
            config=config,
            metric="loss",
            mode="min",
            num_samples=num_samples,
            time_budget_s=time_budget_s,
            scheduler=scheduler,
            search_alg=algo,
        )
    ray.shutdown()

    logger.info(f"method={method}")
    logger.info(f"#trials={len(result.trials)}")
    logger.info(f"time={time.time()-start_time}")
    best_trial = result.get_best_trial("loss", "min", "all")
    logger.info("Best trial config: {}".format(best_trial.config))
    logger.info("Best trial final validation loss: {}".format(
        best_trial.metric_analysis["loss"]["min"]))
    logger.info("Best trial final validation accuracy: {}".format(
        best_trial.metric_analysis["accuracy"]["max"]))

    best_trained_model = Net(2**best_trial.config["l1"],
                             2**best_trial.config["l2"])
    device = "cpu"
    if torch.cuda.is_available():
        device = "cuda:0"
        if gpus_per_trial > 1:
            best_trained_model = nn.DataParallel(best_trained_model)
    best_trained_model.to(device)

    checkpoint_path = os.path.join(best_trial.checkpoint.value, "checkpoint")

    model_state, optimizer_state = torch.load(checkpoint_path)
    best_trained_model.load_state_dict(model_state)

    test_acc = _test_accuracy(best_trained_model, device)
    logger.info("Best trial test set accuracy: {}".format(test_acc))
Beispiel #15
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        with open(checkpoint_path) as f:
            self.timestep = json.loads(f.read())["timestep"]


if __name__ == "__main__":
    import ConfigSpace as CS
    ray.init(redis_address=args.ray_redis_address)

    # BOHB uses ConfigSpace for their hyperparameter search space
    config_space = CS.ConfigurationSpace()
    config_space.add_hyperparameter(
        CS.UniformFloatHyperparameter("height", lower=10, upper=100))
    config_space.add_hyperparameter(
        CS.UniformFloatHyperparameter("width", lower=0, upper=100))

    experiment_metrics = dict(metric="episode_reward_mean", mode="max")
    bohb_hyperband = HyperBandForBOHB(time_attr="training_iteration",
                                      max_t=100,
                                      reduction_factor=4,
                                      **experiment_metrics)
    bohb_search = TuneBOHB(config_space,
                           max_concurrent=4,
                           **experiment_metrics)

    run(MyTrainableClass,
        name="bohb_test",
        scheduler=bohb_hyperband,
        search_alg=bohb_search,
        num_samples=10,
        stop={"training_iteration": 10 if args.smoke_test else 100})
Beispiel #16
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def main(args):
    cfg = setup(args)

    exp_metrics = dict(metric="score", mode="max")

    if args.srch_algo == "hyperopt":
        # Create a HyperOpt search space
        search_space = {
            # "lr": hp.loguniform("lr", np.log(1e-6), np.log(1e-3)),
            # "delay_epochs": hp.randint("delay_epochs", 20, 60),
            # "wd": hp.uniform("wd", 0, 1e-3),
            # "wd_bias": hp.uniform("wd_bias", 0, 1e-3),
            "bsz": hp.choice("bsz", [64, 96, 128, 160, 224, 256]),
            "num_inst": hp.choice("num_inst", [2, 4, 8, 16, 32]),
            # "ce_scale": hp.uniform("ce_scale", 0.1, 1.0),
            # "circle_scale": hp.choice("circle_scale", [16, 32, 64, 128, 256]),
            # "circle_margin": hp.uniform("circle_margin", 0, 1) * 0.4 + 0.1,
        }

        current_best_params = [{
            "bsz": 0,  # index of hp.choice list
            "num_inst": 3,
        }]

        search_algo = HyperOptSearch(search_space,
                                     points_to_evaluate=current_best_params,
                                     **exp_metrics)

        if args.pbt:
            scheduler = PopulationBasedTraining(
                time_attr="training_iteration",
                **exp_metrics,
                perturbation_interval=2,
                hyperparam_mutations={
                    "bsz": [64, 96, 128, 160, 224, 256],
                    "num_inst": [2, 4, 8, 16, 32],
                })
        else:
            scheduler = ASHAScheduler(grace_period=2,
                                      reduction_factor=3,
                                      max_t=7,
                                      **exp_metrics)

    elif args.srch_algo == "bohb":
        search_space = CS.ConfigurationSpace()
        search_space.add_hyperparameters([
            # CS.UniformFloatHyperparameter(name="lr", lower=1e-6, upper=1e-3, log=True),
            # CS.UniformIntegerHyperparameter(name="delay_epochs", lower=20, upper=60),
            # CS.UniformFloatHyperparameter(name="ce_scale", lower=0.1, upper=1.0),
            # CS.UniformIntegerHyperparameter(name="circle_scale", lower=8, upper=128),
            # CS.UniformFloatHyperparameter(name="circle_margin", lower=0.1, upper=0.5),
            # CS.UniformFloatHyperparameter(name="wd", lower=0, upper=1e-3),
            # CS.UniformFloatHyperparameter(name="wd_bias", lower=0, upper=1e-3),
            CS.CategoricalHyperparameter(name="bsz",
                                         choices=[64, 96, 128, 160, 224, 256]),
            CS.CategoricalHyperparameter(name="num_inst",
                                         choices=[2, 4, 8, 16, 32]),
            # CS.CategoricalHyperparameter(name="autoaug_enabled", choices=[True, False]),
            # CS.CategoricalHyperparameter(name="cj_enabled", choices=[True, False]),
        ])

        search_algo = TuneBOHB(search_space, max_concurrent=4, **exp_metrics)

        scheduler = HyperBandForBOHB(
            time_attr="training_iteration",
            reduction_factor=3,
            max_t=7,
            **exp_metrics,
        )

    else:
        raise ValueError(
            "Search algorithm must be chosen from [hyperopt, bohb], but got {}"
            .format(args.srch_algo))

    reporter = CLIReporter(parameter_columns=["bsz", "num_inst"],
                           metric_columns=["r1", "map", "training_iteration"])

    analysis = tune.run(partial(train_tuner, cfg=cfg),
                        resources_per_trial={
                            "cpu": 4,
                            "gpu": 1
                        },
                        search_alg=search_algo,
                        num_samples=args.num_trials,
                        scheduler=scheduler,
                        progress_reporter=reporter,
                        local_dir=cfg.OUTPUT_DIR,
                        keep_checkpoints_num=10,
                        name=args.srch_algo)

    best_trial = analysis.get_best_trial("score", "max", "last")
    logger.info("Best trial config: {}".format(best_trial.config))
    logger.info("Best trial final validation mAP: {}, Rank-1: {}".format(
        best_trial.last_result["map"], best_trial.last_result["r1"]))

    save_dict = dict(R1=best_trial.last_result["r1"].item(),
                     mAP=best_trial.last_result["map"].item())
    save_dict.update(best_trial.config)
    path = os.path.join(cfg.OUTPUT_DIR, "best_config.yaml")
    with PathManager.open(path, "w") as f:
        f.write(CfgNode(save_dict).dump())
    logger.info("Best config saved to {}".format(os.path.abspath(path)))
Beispiel #17
0
def cifar10_main(method='BlendSearch',
                 num_samples=10,
                 max_num_epochs=100,
                 gpus_per_trial=2):
    data_dir = os.path.abspath("test/data")
    load_data(data_dir)  # Download data for all trials before starting the run
    if method == 'BlendSearch':
        from flaml import tune
    else:
        from ray import tune
    if method in ['BlendSearch', 'BOHB', 'Optuna']:
        config = {
            "l1": tune.randint(2, 8),
            "l2": tune.randint(2, 8),
            "lr": tune.loguniform(1e-4, 1e-1),
            "num_epochs": tune.qloguniform(1, max_num_epochs, q=1),
            "batch_size": tune.randint(1, 4)  #tune.choice([2, 4, 8, 16])
        }
    else:
        config = {
            "l1": tune.randint(2, 9),
            "l2": tune.randint(2, 9),
            "lr": tune.loguniform(1e-4, 1e-1),
            "num_epochs": tune.qloguniform(1, max_num_epochs + 1, q=1),
            "batch_size": tune.randint(1, 5)  #tune.choice([2, 4, 8, 16])
        }
    import ray
    time_budget_s = 3600
    start_time = time.time()
    if method == 'BlendSearch':
        result = tune.run(ray.tune.with_parameters(train_cifar,
                                                   data_dir=data_dir),
                          init_config={
                              "l1": 2,
                              "l2": 2,
                              "num_epochs": 1,
                              "batch_size": 4,
                          },
                          metric="loss",
                          mode="min",
                          max_resource=max_num_epochs,
                          min_resource=1,
                          report_intermediate_result=True,
                          resources_per_trial={
                              "cpu": 2,
                              "gpu": gpus_per_trial
                          },
                          config=config,
                          local_dir='logs/',
                          num_samples=num_samples,
                          time_budget_s=time_budget_s,
                          use_ray=True)
    else:
        if 'ASHA' == method:
            algo = None
        elif 'BOHB' == method:
            from ray.tune.schedulers import HyperBandForBOHB
            from ray.tune.suggest.bohb import TuneBOHB
            algo = TuneBOHB()
            scheduler = HyperBandForBOHB(max_t=max_num_epochs)
        elif 'Optuna' == method:
            from ray.tune.suggest.optuna import OptunaSearch
            algo = OptunaSearch()
        elif 'CFO' == method:
            from flaml import CFO
            algo = CFO(points_to_evaluate=[{
                "l1": 2,
                "l2": 2,
                "num_epochs": 1,
                "batch_size": 4,
            }])
        elif 'Nevergrad' == method:
            from ray.tune.suggest.nevergrad import NevergradSearch
            import nevergrad as ng
            algo = NevergradSearch(optimizer=ng.optimizers.OnePlusOne)
        if method != 'BOHB':
            from ray.tune.schedulers import ASHAScheduler
            scheduler = ASHAScheduler(max_t=max_num_epochs, grace_period=1)
        result = tune.run(tune.with_parameters(train_cifar, data_dir=data_dir),
                          resources_per_trial={
                              "cpu": 2,
                              "gpu": gpus_per_trial
                          },
                          config=config,
                          metric="loss",
                          mode="min",
                          num_samples=num_samples,
                          time_budget_s=time_budget_s,
                          scheduler=scheduler,
                          search_alg=algo)
    ray.shutdown()

    logger.info(f"method={method}")
    logger.info(f"n_samples={num_samples}")
    logger.info(f"time={time.time()-start_time}")
    best_trial = result.get_best_trial("loss", "min", "all")
    logger.info("Best trial config: {}".format(best_trial.config))
    logger.info("Best trial final validation loss: {}".format(
        best_trial.metric_analysis["loss"]["min"]))
    logger.info("Best trial final validation accuracy: {}".format(
        best_trial.metric_analysis["accuracy"]["max"]))

    best_trained_model = Net(2**best_trial.config["l1"],
                             2**best_trial.config["l2"])
    device = "cpu"
    if torch.cuda.is_available():
        device = "cuda:0"
        if gpus_per_trial > 1:
            best_trained_model = nn.DataParallel(best_trained_model)
    best_trained_model.to(device)

    checkpoint_path = os.path.join(best_trial.checkpoint.value, "checkpoint")

    model_state, optimizer_state = torch.load(checkpoint_path)
    best_trained_model.load_state_dict(model_state)

    test_acc = _test_accuracy(best_trained_model, device)
    logger.info("Best trial test set accuracy: {}".format(test_acc))
Beispiel #18
0
def get_raytune_search_alg(raytune_cfg, seeds=False):
    if (raytune_cfg["sched"] == "pbt") or (raytune_cfg["sched"] == "pb2"):
        if raytune_cfg["search_alg"] is not None:
            print(
                "INFO: Using schedule '{}' is not compatible with Ray Tune search algorithms."
                .format(raytune_cfg["sched"]))
            print(
                "INFO: Uing the Ray Tune {} scheduler without search algorithm"
                .format(raytune_cfg["sched"]))
        return None

    if (raytune_cfg["sched"] == "bohb") or (raytune_cfg["sched"] == "BOHB"):
        print(
            "INFO: Using TuneBOHB search algorithm since it is required for BOHB shedule"
        )
        if seeds:
            seed = 1234
        else:
            seed = None
        return TuneBOHB(metric=raytune_cfg["default_metric"],
                        mode=raytune_cfg["default_mode"],
                        seed=seed)

    # requires pip install bayesian-optimization
    if raytune_cfg["search_alg"] == "bayes":
        print("INFO: Using BayesOptSearch")
        return BayesOptSearch(
            metric=raytune_cfg["default_metric"],
            mode=raytune_cfg["default_mode"],
            random_search_steps=raytune_cfg["bayes"]["n_random_steps"],
        )

    # requires pip install hyperopt
    if raytune_cfg["search_alg"] == "hyperopt":
        print("INFO: Using HyperOptSearch")
        return HyperOptSearch(
            metric=raytune_cfg["default_metric"],
            mode=raytune_cfg["default_mode"],
            n_initial_points=raytune_cfg["hyperopt"]["n_random_steps"],
            # points_to_evaluate=,
        )
    if raytune_cfg["search_alg"] == "scikit":
        print("INFO: Using bayesian optimization from scikit-learn")
        return SkOptSearch(
            metric=raytune_cfg["default_metric"],
            mode=raytune_cfg["default_mode"],
            convert_to_python=True,
        )
    if raytune_cfg["search_alg"] == "nevergrad":
        print("INFO: Using bayesian optimization from nevergrad")
        return NevergradSearch(
            optimizer=ng.optimizers.BayesOptim(
                pca=False,
                init_budget=raytune_cfg["nevergrad"]["n_random_steps"]),
            metric=raytune_cfg["default_metric"],
            mode=raytune_cfg["default_mode"],
        )
    # HEBO is not yet supported
    # if (raytune_cfg["search_alg"] == "hebo") or (raytune_cfg["search_alg"] == "HEBO"):
    #     print("Using HEBOSearch")
    #     return HEBOSearch(
    #         metric=raytune_cfg["default_metric"],
    #         mode=raytune_cfg["default_mode"],
    #         # max_concurrent=8,
    #     )
    else:
        print("INFO: Not using any Ray Tune search algorithm")
        return None
Beispiel #19
0
def main(args):
    def trainable(config):
        print('begin a trial')
        args.params = tools.AttrDict(yaml.safe_load(args.params.replace('#', ',')))
        args.logdir = args.logdir and os.path.expanduser(args.logdir)
        print('debug ', config["divergence_scale"], config["reward_loss_scale"])
        with args.params.unlocked:
            args.params.divergence_scale = config["divergence_scale"]
            args.params.reward_loss_scale = config["reward_loss_scale"]
            # args.params.main_learning_rate = config["main_learning_rate"]
            args.params.test_steps = 50
            # args.params.num_units = config['num_units']
            args.params.test_traj = 5
        training.utility.set_up_logging()
        experiment = training.Experiment(
            args.logdir,
            process_fn=functools.partial(process, args=args),
            num_runs=args.num_runs,
            ping_every=args.ping_every,
            resume_runs=args.resume_runs)
        for run in experiment:
            for test_score in run:
                if test_score > 1.0:
                    tune.report(mean_score=test_score)
            break

    import ConfigSpace as CS
    import ConfigSpace.hyperparameters as CSH
    # search = {
    #     "divergence_scale": tune.quniform(1, 30, 1),
    #     "reward_loss_scale": tune.quniform(1, 50, 1),
    # }
    search = {
        "divergence_scale": tune.grid_search([0.1, 1, 2, 3, 5, 10]),
        "reward_loss_scale": tune.grid_search([1, 2, 5, 10, 20]),
    }
    config_space = CS.ConfigurationSpace(seed=1234)
    config_space.add_hyperparameter(
        CSH.UniformIntegerHyperparameter(name="divergence_scale", lower=1, upper=30))
    config_space.add_hyperparameter(
        CSH.UniformIntegerHyperparameter(name="reward_loss_scale", lower=1, upper=50))
    # config_space.add_hyperparameter(
    #     CSH.UniformFloatHyperparameter("main_learning_rate", lower=0.0001, upper=0.05, log=True))
    config_space.add_hyperparameter(
        CSH.UniformIntegerHyperparameter("main_learning_rate", lower=1, upper=500, log=True))
    config_space.add_hyperparameter(
        CSH.UniformIntegerHyperparameter(name="num_units", lower=150, upper=400, q=50))
    bayesopt = BayesOptSearch(metric="mean_loss", mode="min")
    bohb_hyperband = HyperBandForBOHB(metric="mean_score", mode="max", time_attr="training_iteration", max_t=30,
                                      reduction_factor=3)
    bohb_search = TuneBOHB(space=config_space, max_concurrent=1, metric="mean_score", mode="max")
    bayesopt = BayesOptSearch(max_concurrent=3, metric="mean_score", mode="max")
    asha = ASHAScheduler(metric="mean_score", mode="max", grace_period=6, reduction_factor=3)
    analysis = tune.run(
        trainable,
        config=search,
        num_samples=3,
        scheduler=asha,
        resources_per_trial={"cpu": 16, "gpu": 1},
        stop={"training_iteration": 13},
        # search_alg=bayesopt,
        log_to_file=True
    )
    df = analysis.results_df
    print("Best config: ", analysis.get_best_config(
        metric="mean_score", mode="min"))
    print(df)
Beispiel #20
0
    def _tune_run(self, config, resources_per_trial):
        """Wrapper to call ``tune.run``. Multiple estimators are generated when
        early stopping is possible, whereas a single estimator is
        generated when early stopping is not possible.

        Args:
            config (dict): Configurations such as hyperparameters to run
            ``tune.run`` on.
            resources_per_trial (dict): Resources to use per trial within Ray.
                Accepted keys are `cpu`, `gpu` and custom resources, and values
                are integers specifying the number of each resource to use.

        Returns:
            analysis (`ExperimentAnalysis`): Object returned by
                `tune.run`.

        """
        stop_condition = {"training_iteration": self.max_iters}
        if self.early_stopping is not None:
            config["estimator_list"] = [
                clone(self.estimator) for _ in range(self.n_splits)
            ]
            if hasattr(self.early_stopping, "_max_t_attr"):
                # we want to delegate stopping to schedulers which
                # support it, but we want it to stop eventually, just in case
                # the solution is to make the stop condition very big
                stop_condition = {"training_iteration": self.max_iters * 10}
        else:
            config["estimator_list"] = [self.estimator]

        if self.search_optimization == "random":
            run_args = dict(scheduler=self.early_stopping,
                            reuse_actors=True,
                            verbose=self.verbose,
                            stop=stop_condition,
                            num_samples=self.num_samples,
                            config=config,
                            fail_fast=True,
                            resources_per_trial=resources_per_trial,
                            local_dir=os.path.expanduser(self.local_dir))

            if isinstance(self.param_distributions, list):
                run_args["search_alg"] = RandomListSearcher(
                    self.param_distributions)

            analysis = tune.run(_Trainable, **run_args)
            return analysis

        elif self.search_optimization == "bayesian":
            from skopt import Optimizer
            from ray.tune.suggest.skopt import SkOptSearch
            hyperparameter_names, spaces = self._get_skopt_params()
            search_algo = SkOptSearch(Optimizer(spaces),
                                      hyperparameter_names,
                                      metric="average_test_score",
                                      **self.search_kwargs)

        elif self.search_optimization == "bohb":
            from ray.tune.suggest.bohb import TuneBOHB
            config_space = self._get_bohb_config_space()
            search_algo = TuneBOHB(config_space,
                                   metric="average_test_score",
                                   mode="max",
                                   **self.search_kwargs)

        elif self.search_optimization == "optuna":
            from ray.tune.suggest.optuna import OptunaSearch
            config_space = self._get_optuna_params()
            search_algo = OptunaSearch(config_space,
                                       metric="average_test_score",
                                       mode="max",
                                       **self.search_kwargs)

        elif self.search_optimization == "hyperopt":
            from ray.tune.suggest.hyperopt import HyperOptSearch
            config_space = self._get_hyperopt_params()
            search_algo = HyperOptSearch(config_space,
                                         metric="average_test_score",
                                         mode="max",
                                         **self.search_kwargs)

        if isinstance(self.n_jobs, int) and self.n_jobs > 0:
            search_algo = ConcurrencyLimiter(search_algo,
                                             max_concurrent=self.n_jobs)

        analysis = tune.run(_Trainable,
                            search_alg=search_algo,
                            scheduler=self.early_stopping,
                            reuse_actors=True,
                            verbose=self.verbose,
                            stop=stop_condition,
                            num_samples=self.num_samples,
                            config=config,
                            fail_fast=True,
                            resources_per_trial=resources_per_trial,
                            local_dir=os.path.expanduser(self.local_dir))

        return analysis
Beispiel #21
0
    # gin-config
    gin.parse_config_files_and_bindings(['configs/config.gin'], bindings)
    utils_params.save_config(run_paths['path_gin'], gin.config_str())

    # setup pipeline
    ds_train, ds_val, ds_test = load_from_tfrecords()

    # model
    model = TransformerS2S()

    trainer = Trainer(model, ds_train, ds_val, run_paths)
    for val_accuracy in trainer.train():
        tune.report(val_accuracy=val_accuracy)


algo = TuneBOHB(max_concurrent=4, metric="val_accuracy", mode="max")
bohb = HyperBandForBOHB(time_attr="training_iteration",
                        metric="val_accuracy",
                        mode="max",
                        max_t=100)

config_name = 'transformerS2S'

if config_name == 'lstm':
    config = {
        "LSTM.rnn_units1": tune.randint(16, 64),
        "LSTM.rnn_units2": tune.randint(8, 32),
        "LSTM.dense_units": tune.randint(12, 64),
        "LSTM.dropout_rate": tune.uniform(0, 0.8),
        "load_from_tfrecords.batch_size": tune.choice([8, 16, 32, 64, 128])
    }
Beispiel #22
0
    def _tune_run(self, config, resources_per_trial):
        """Wrapper to call ``tune.run``. Multiple estimators are generated when
        early stopping is possible, whereas a single estimator is
        generated when early stopping is not possible.

        Args:
            config (dict): Configurations such as hyperparameters to run
            ``tune.run`` on.
            resources_per_trial (dict): Resources to use per trial within Ray.
                Accepted keys are `cpu`, `gpu` and custom resources, and values
                are integers specifying the number of each resource to use.

        Returns:
            analysis (`ExperimentAnalysis`): Object returned by
                `tune.run`.

        """
        if self.seed is not None:
            random.seed(self.seed)
            np.random.seed(self.seed)

        trainable = _Trainable
        if self.pipeline_auto_early_stop and check_is_pipeline(
                self.estimator) and self.early_stopping:
            trainable = _PipelineTrainable

        max_iter = self.max_iters
        if self.early_stopping is not None:
            config["estimator_list"] = [
                clone(self.estimator) for _ in range(self.n_splits)
            ]
            if hasattr(self.early_stopping, "_max_t_attr"):
                # we want to delegate stopping to schedulers which
                # support it, but we want it to stop eventually, just in case
                # the solution is to make the stop condition very big
                max_iter = self.max_iters * 10
        else:
            config["estimator_list"] = [self.estimator]

        stopper = MaximumIterationStopper(max_iter=max_iter)
        if self.stopper:
            stopper = CombinedStopper(stopper, self.stopper)

        run_args = dict(scheduler=self.early_stopping,
                        reuse_actors=True,
                        verbose=self.verbose,
                        stop=stopper,
                        num_samples=self.n_trials,
                        config=config,
                        fail_fast="raise",
                        resources_per_trial=resources_per_trial,
                        local_dir=os.path.expanduser(self.local_dir),
                        loggers=self.loggers,
                        time_budget_s=self.time_budget_s)

        if self.search_optimization == "random":
            if isinstance(self.param_distributions, list):
                search_algo = RandomListSearcher(self.param_distributions)
            else:
                search_algo = BasicVariantGenerator()
            run_args["search_alg"] = search_algo
        else:
            search_space = None
            override_search_space = True
            if self._is_param_distributions_all_tune_domains():
                run_args["config"].update(self.param_distributions)
                override_search_space = False

            search_kwargs = self.search_kwargs.copy()
            search_kwargs.update(metric=self._metric_name, mode="max")

            if self.search_optimization == "bayesian":
                from ray.tune.suggest.skopt import SkOptSearch
                if override_search_space:
                    search_space = self.param_distributions
                search_algo = SkOptSearch(space=search_space, **search_kwargs)
                run_args["search_alg"] = search_algo

            elif self.search_optimization == "bohb":
                from ray.tune.suggest.bohb import TuneBOHB
                if override_search_space:
                    search_space = self._get_bohb_config_space()
                if self.seed:
                    warnings.warn("'seed' is not implemented for BOHB.")
                search_algo = TuneBOHB(space=search_space, **search_kwargs)
                # search_algo = TuneBOHB(
                #     space=search_space, seed=self.seed, **search_kwargs)
                run_args["search_alg"] = search_algo

            elif self.search_optimization == "optuna":
                from ray.tune.suggest.optuna import OptunaSearch
                from optuna.samplers import TPESampler
                sampler = TPESampler(seed=self.seed)
                if override_search_space:
                    search_space = self._get_optuna_params()
                search_algo = OptunaSearch(space=search_space,
                                           sampler=sampler,
                                           **search_kwargs)
                run_args["search_alg"] = search_algo

            elif self.search_optimization == "hyperopt":
                from ray.tune.suggest.hyperopt import HyperOptSearch
                if override_search_space:
                    search_space = self._get_hyperopt_params()
                search_algo = HyperOptSearch(space=search_space,
                                             random_state_seed=self.seed,
                                             **search_kwargs)
                run_args["search_alg"] = search_algo

            else:
                # This should not happen as we validate the input before
                # this method. Still, just to be sure, raise an error here.
                raise ValueError(
                    f"Invalid search optimizer: {self.search_optimization}")

        if isinstance(self.n_jobs, int) and self.n_jobs > 0 \
           and not self.search_optimization == "random":
            search_algo = ConcurrencyLimiter(search_algo,
                                             max_concurrent=self.n_jobs)
            run_args["search_alg"] = search_algo

        with warnings.catch_warnings():
            warnings.filterwarnings("ignore",
                                    message="fail_fast='raise' "
                                    "detected.")
            analysis = tune.run(trainable, **run_args)
        return analysis
Beispiel #23
0
def tune(args):

    search_space = get_search_space(args.config_name)
    config = get_config(args.config_name)

    store = get_target_path(config, 'hptune')

    if args.overwrite:
        if os.path.isdir(store):
            shutil.rmtree(store)
    else:
        if os.path.isdir(store):
            raise ValueError(
                f'The tune directory {store} exists. Set flag "--overwrite" '
                'if you want to overwrite runs - all existing runs will be lost!')
    os.makedirs(store)

    config.update({
        'is_tune': True,
        'small_aoi': args.small_aoi,
    })

    ngpu = torch.cuda.device_count()
    ncpu = os.cpu_count()

    max_concurrent = int(
        np.min((
            np.floor(ncpu / config['ncpu_per_run']),
            np.floor(ngpu / config['ngpu_per_run'])
        ))
    )

    print(
        '\nTuning hyperparameters;\n'
        f'  Available resources: {ngpu} GPUs | {ncpu} CPUs\n'
        f'  Number of concurrent runs: {max_concurrent}\n'
    )

    bobh_search = TuneBOHB(
        space=search_space,
        max_concurrent=max_concurrent,
        metric=config['metric'],
        mode='min'
    )

    bohb_scheduler = HyperBandForBOHB(
        time_attr='epoch',
        metric=config['metric'],
        mode='min',
        max_t=config['max_t'],
        reduction_factor=config['halving_factor'])

    if args.run_single:
        logging.warning('Starting test run.')
        e = Emulator(search_space.sample_configuration())
        logging.warning('Starting training loop.')
        e._train()
        logging.warning('Finishing test run.')
        sys.exit('0')

    ray.tune.run(
        Emulator,
        config={'hc_config': config},
        resources_per_trial={
            'cpu': config['ncpu_per_run'],
            'gpu': config['ngpu_per_run']},
        num_samples=config['num_samples'],
        local_dir=store,
        raise_on_failed_trial=True,
        verbose=1,
        with_server=False,
        ray_auto_init=False,
        search_alg=bobh_search,
        scheduler=bohb_scheduler,
        loggers=[JsonLogger, CSVLogger],
        keep_checkpoints_num=1,
        reuse_actors=False,
        stop={'patience_counter': config['patience']}
    )

    summarize_run(store, overwrite=True)
Beispiel #24
0
def _test_xgboost(method="BlendSearch"):
    try:
        import ray
    except ImportError:
        return
    if method == "BlendSearch":
        from flaml import tune
    else:
        from ray import tune
    search_space = {
        "max_depth":
        tune.randint(1, 9)
        if method in ["BlendSearch", "BOHB", "Optuna"] else tune.randint(1, 9),
        "min_child_weight":
        tune.choice([1, 2, 3]),
        "subsample":
        tune.uniform(0.5, 1.0),
        "eta":
        tune.loguniform(1e-4, 1e-1),
    }
    max_iter = 10
    for num_samples in [128]:
        time_budget_s = 60
        for n_cpu in [2]:
            start_time = time.time()
            # ray.init(address='auto')
            if method == "BlendSearch":
                analysis = tune.run(
                    train_breast_cancer,
                    config=search_space,
                    low_cost_partial_config={
                        "max_depth": 1,
                    },
                    cat_hp_cost={
                        "min_child_weight": [6, 3, 2],
                    },
                    metric="eval-logloss",
                    mode="min",
                    max_resource=max_iter,
                    min_resource=1,
                    scheduler="asha",
                    # You can add "gpu": 0.1 to allocate GPUs
                    resources_per_trial={"cpu": 1},
                    local_dir="logs/",
                    num_samples=num_samples * n_cpu,
                    time_budget_s=time_budget_s,
                    use_ray=True,
                )
            else:
                if "ASHA" == method:
                    algo = None
                elif "BOHB" == method:
                    from ray.tune.schedulers import HyperBandForBOHB
                    from ray.tune.suggest.bohb import TuneBOHB

                    algo = TuneBOHB(max_concurrent=n_cpu)
                    scheduler = HyperBandForBOHB(max_t=max_iter)
                elif "Optuna" == method:
                    from ray.tune.suggest.optuna import OptunaSearch

                    algo = OptunaSearch()
                elif "CFO" == method:
                    from flaml import CFO

                    algo = CFO(
                        low_cost_partial_config={
                            "max_depth": 1,
                        },
                        cat_hp_cost={
                            "min_child_weight": [6, 3, 2],
                        },
                    )
                elif "CFOCat" == method:
                    from flaml.searcher.cfo_cat import CFOCat

                    algo = CFOCat(
                        low_cost_partial_config={
                            "max_depth": 1,
                        },
                        cat_hp_cost={
                            "min_child_weight": [6, 3, 2],
                        },
                    )
                elif "Dragonfly" == method:
                    from ray.tune.suggest.dragonfly import DragonflySearch

                    algo = DragonflySearch()
                elif "SkOpt" == method:
                    from ray.tune.suggest.skopt import SkOptSearch

                    algo = SkOptSearch()
                elif "Nevergrad" == method:
                    from ray.tune.suggest.nevergrad import NevergradSearch
                    import nevergrad as ng

                    algo = NevergradSearch(optimizer=ng.optimizers.OnePlusOne)
                elif "ZOOpt" == method:
                    from ray.tune.suggest.zoopt import ZOOptSearch

                    algo = ZOOptSearch(budget=num_samples * n_cpu)
                elif "Ax" == method:
                    from ray.tune.suggest.ax import AxSearch

                    algo = AxSearch()
                elif "HyperOpt" == method:
                    from ray.tune.suggest.hyperopt import HyperOptSearch

                    algo = HyperOptSearch()
                    scheduler = None
                if method != "BOHB":
                    from ray.tune.schedulers import ASHAScheduler

                    scheduler = ASHAScheduler(max_t=max_iter, grace_period=1)
                analysis = tune.run(
                    train_breast_cancer,
                    metric="eval-logloss",
                    mode="min",
                    # You can add "gpu": 0.1 to allocate GPUs
                    resources_per_trial={"cpu": 1},
                    config=search_space,
                    local_dir="logs/",
                    num_samples=num_samples * n_cpu,
                    time_budget_s=time_budget_s,
                    scheduler=scheduler,
                    search_alg=algo,
                )
            # # Load the best model checkpoint
            # import os
            # best_bst = xgb.Booster()
            # best_bst.load_model(os.path.join(analysis.best_checkpoint,
            #  "model.xgb"))
            best_trial = analysis.get_best_trial("eval-logloss", "min", "all")
            accuracy = 1.0 - best_trial.metric_analysis["eval-error"]["min"]
            logloss = best_trial.metric_analysis["eval-logloss"]["min"]
            logger.info(f"method={method}")
            logger.info(f"n_samples={num_samples*n_cpu}")
            logger.info(f"time={time.time()-start_time}")
            logger.info(f"Best model eval loss: {logloss:.4f}")
            logger.info(f"Best model total accuracy: {accuracy:.4f}")
            logger.info(f"Best model parameters: {best_trial.config}")
Beispiel #25
0
def hparams(algorithm, scheduler, num_samples, tensorboard, bare):
    from glob import glob

    import tensorflow.summary
    from tensorflow import random as tfrandom, int64 as tfint64
    from ray import init as init_ray, shutdown as shutdown_ray
    from ray import tune
    from wandb.ray import WandbLogger
    from wandb import sweep as wandbsweep
    from wandb.apis import CommError as wandbCommError

    # less summaries are logged if MLENCRYPT_TB is TRUE (for efficiency)
    # TODO: use tf.summary.record_if?
    environ["MLENCRYPT_TB"] = str(tensorboard).upper()
    environ["MLENCRYPT_BARE"] = str(bare).upper()
    if getenv('MLENCRYPT_TB', 'FALSE') == 'TRUE' and \
            getenv('MLENCRYPT_BARE', 'FALSE') == 'TRUE':
        raise ValueError('TensorBoard logging cannot be enabled in bare mode.')

    logdir = f'logs/hparams/{datetime.now()}'

    # "These results show that K = 3 is the optimal choice for the
    # cryptographic application of neural synchronization. K = 1 and K = 2 are
    # too insecure in regard to the geometric attack. And for K > 3 the effort
    # of A and B grows exponentially with increasing L, while the simple attack
    # is quite successful in the limit K -> infinity. Consequently, one should
    # only use Tree Parity Machines with three hidden units for the neural
    # key-exchange protocol." (Ruttor, 2006)
    # https://arxiv.org/pdf/0711.2411.pdf#page=59

    update_rules = [
        'random-same',
        # 'random-different-A-B-E', 'random-different-A-B',
        'hebbian',
        'anti_hebbian',
        'random_walk'
    ]
    K_bounds = {'min': 4, 'max': 8}
    N_bounds = {'min': 4, 'max': 8}
    L_bounds = {'min': 4, 'max': 8}

    # TODO: don't use *_bounds.values() since .values doesn't preserve order

    def get_session_num(logdir):
        current_runs = glob(join(logdir, "run-*"))
        if current_runs:
            last_run_path = current_runs[-1]
            last_run_session_num = int(last_run_path.split('-')[-1])
            return last_run_session_num + 1
        else:  # there are no runs yet, start at 0
            return 0

    def trainable(config, reporter):
        """
        Args:
            config (dict): Parameters provided from the search algorithm
                or variant generation.
        """
        if not isinstance(config['update_rule'], str):
            update_rule = update_rules[int(config['update_rule'])]
        else:
            update_rule = config['update_rule']
        K, N, L = int(config['K']), int(config['N']), int(config['L'])

        run_name = f"run-{get_session_num(logdir)}"
        run_logdir = join(logdir, run_name)
        # for each attack, the TPMs should start with the same weights
        initial_weights_tensors = get_initial_weights(K, N, L)
        training_steps_ls = {}
        eve_scores_ls = {}
        losses_ls = {}
        # for each attack, the TPMs should use the same inputs
        seed = tfrandom.uniform([],
                                minval=0,
                                maxval=tfint64.max,
                                dtype=tfint64).numpy()
        for attack in ['none', 'geometric']:
            initial_weights = {
                tpm: weights_tensor_to_variable(weights, tpm)
                for tpm, weights in initial_weights_tensors.items()
            }
            tfrandom.set_seed(seed)

            if tensorboard:
                attack_logdir = join(run_logdir, attack)
                attack_writer = tensorflow.summary.create_file_writer(
                    attack_logdir)
                with attack_writer.as_default():
                    training_steps, sync_scores, loss = run(
                        update_rule, K, N, L, attack, initial_weights)
            else:
                training_steps, sync_scores, loss = run(
                    update_rule, K, N, L, attack, initial_weights)
            training_steps_ls[attack] = training_steps
            eve_scores_ls[attack] = sync_scores
            losses_ls[attack] = loss
        avg_training_steps = tensorflow.math.reduce_mean(
            list(training_steps_ls.values()))
        avg_eve_score = tensorflow.math.reduce_mean(
            list(eve_scores_ls.values()))
        mean_loss = tensorflow.math.reduce_mean(list(losses_ls.values()))
        reporter(
            avg_training_steps=avg_training_steps.numpy(),
            avg_eve_score=avg_eve_score.numpy(),
            mean_loss=mean_loss.numpy(),
            done=True,
        )

    if algorithm == 'hyperopt':
        from hyperopt import hp as hyperopt
        from hyperopt.pyll.base import scope
        from ray.tune.suggest.hyperopt import HyperOptSearch

        space = {
            'update_rule': hyperopt.choice(
                'update_rule',
                update_rules,
            ),
            'K': scope.int(hyperopt.quniform('K', *K_bounds.values(), q=1)),
            'N': scope.int(hyperopt.quniform('N', *N_bounds.values(), q=1)),
            'L': scope.int(hyperopt.quniform('L', *L_bounds.values(), q=1)),
        }
        algo = HyperOptSearch(
            space,
            metric='mean_loss',
            mode='min',
            points_to_evaluate=[
                {
                    'update_rule': 0,
                    'K': 3,
                    'N': 16,
                    'L': 8
                },
                {
                    'update_rule': 0,
                    'K': 8,
                    'N': 16,
                    'L': 8
                },
                {
                    'update_rule': 0,
                    'K': 8,
                    'N': 16,
                    'L': 128
                },
            ],
        )
    elif algorithm == 'bayesopt':
        from ray.tune.suggest.bayesopt import BayesOptSearch

        space = {
            'update_rule': (0, len(update_rules)),
            'K': tuple(K_bounds.values()),
            'N': tuple(N_bounds.values()),
            'L': tuple(L_bounds.values()),
        }
        algo = BayesOptSearch(
            space,
            metric="mean_loss",
            mode="min",
            # TODO: what is utility_kwargs for and why is it needed?
            utility_kwargs={
                "kind": "ucb",
                "kappa": 2.5,
                "xi": 0.0
            })
    elif algorithm == 'nevergrad':
        from ray.tune.suggest.nevergrad import NevergradSearch
        from nevergrad import optimizers
        from nevergrad import p as ngp

        algo = NevergradSearch(
            optimizers.TwoPointsDE(
                ngp.Instrumentation(
                    update_rule=ngp.Choice(update_rules),
                    K=ngp.Scalar(lower=K_bounds['min'],
                                 upper=K_bounds['max']).set_integer_casting(),
                    N=ngp.Scalar(lower=N_bounds['min'],
                                 upper=N_bounds['max']).set_integer_casting(),
                    L=ngp.Scalar(lower=L_bounds['min'],
                                 upper=L_bounds['max']).set_integer_casting(),
                )),
            None,  # since the optimizer is already instrumented with kwargs
            metric="mean_loss",
            mode="min")
    elif algorithm == 'skopt':
        from skopt import Optimizer
        from ray.tune.suggest.skopt import SkOptSearch

        optimizer = Optimizer([
            update_rules,
            tuple(K_bounds.values()),
            tuple(N_bounds.values()),
            tuple(L_bounds.values())
        ])
        algo = SkOptSearch(
            optimizer,
            ["update_rule", "K", "N", "L"],
            metric="mean_loss",
            mode="min",
            points_to_evaluate=[
                ['random-same', 3, 16, 8],
                ['random-same', 8, 16, 8],
                ['random-same', 8, 16, 128],
            ],
        )
    elif algorithm == 'dragonfly':
        # TODO: doesn't work
        from ray.tune.suggest.dragonfly import DragonflySearch
        from dragonfly.exd.experiment_caller import EuclideanFunctionCaller
        from dragonfly.opt.gp_bandit import EuclideanGPBandit
        # from dragonfly.exd.experiment_caller import CPFunctionCaller
        # from dragonfly.opt.gp_bandit import CPGPBandit
        from dragonfly import load_config

        domain_config = load_config({
            "domain": [
                {
                    "name": "update_rule",
                    "type": "discrete",
                    "dim": 1,
                    "items": update_rules
                },
                {
                    "name": "K",
                    "type": "int",
                    "min": K_bounds['min'],
                    "max": K_bounds['max'],
                    # "dim": 1
                },
                {
                    "name": "N",
                    "type": "int",
                    "min": N_bounds['min'],
                    "max": N_bounds['max'],
                    # "dim": 1
                },
                {
                    "name": "L",
                    "type": "int",
                    "min": L_bounds['min'],
                    "max": L_bounds['max'],
                    # "dim": 1
                }
            ]
        })
        func_caller = EuclideanFunctionCaller(
            None, domain_config.domain.list_of_domains[0])
        optimizer = EuclideanGPBandit(func_caller, ask_tell_mode=True)
        algo = DragonflySearch(
            optimizer,
            metric="mean_loss",
            mode="min",
            points_to_evaluate=[
                ['random-same', 3, 16, 8],
                ['random-same', 8, 16, 8],
                ['random-same', 8, 16, 128],
            ],
        )
    elif algorithm == 'bohb':
        from ConfigSpace import ConfigurationSpace
        from ConfigSpace import hyperparameters as CSH
        from ray.tune.suggest.bohb import TuneBOHB

        config_space = ConfigurationSpace()
        config_space.add_hyperparameter(
            CSH.CategoricalHyperparameter("update_rule", choices=update_rules))
        config_space.add_hyperparameter(
            CSH.UniformIntegerHyperparameter(name='K',
                                             lower=K_bounds['min'],
                                             upper=K_bounds['max']))
        config_space.add_hyperparameter(
            CSH.UniformIntegerHyperparameter(name='N',
                                             lower=N_bounds['min'],
                                             upper=N_bounds['max']))
        config_space.add_hyperparameter(
            CSH.UniformIntegerHyperparameter(name='L',
                                             lower=L_bounds['min'],
                                             upper=L_bounds['max']))
        algo = TuneBOHB(config_space, metric="mean_loss", mode="min")
    elif algorithm == 'zoopt':
        from ray.tune.suggest.zoopt import ZOOptSearch
        from zoopt import ValueType

        space = {
            "update_rule":
            (ValueType.DISCRETE, range(0, len(update_rules)), False),
            "K": (ValueType.DISCRETE,
                  range(K_bounds['min'], K_bounds['max'] + 1), True),
            "N": (ValueType.DISCRETE,
                  range(N_bounds['min'], N_bounds['max'] + 1), True),
            "L": (ValueType.DISCRETE,
                  range(L_bounds['min'], L_bounds['max'] + 1), True),
        }
        # TODO: change budget to a large value
        algo = ZOOptSearch(budget=10,
                           dim_dict=space,
                           metric="mean_loss",
                           mode="min")

    # TODO: use more appropriate arguments for schedulers:
    # https://docs.ray.io/en/master/tune/api_docs/schedulers.html
    if scheduler == 'fifo':
        sched = None  # Tune defaults to FIFO
    elif scheduler == 'pbt':
        from ray.tune.schedulers import PopulationBasedTraining
        from random import randint
        sched = PopulationBasedTraining(
            metric="mean_loss",
            mode="min",
            hyperparam_mutations={
                "update_rule": update_rules,
                "K": lambda: randint(K_bounds['min'], K_bounds['max']),
                "N": lambda: randint(N_bounds['min'], N_bounds['max']),
                "L": lambda: randint(L_bounds['min'], L_bounds['max']),
            })
    elif scheduler == 'ahb' or scheduler == 'asha':
        # https://docs.ray.io/en/latest/tune/api_docs/schedulers.html#asha-tune-schedulers-ashascheduler
        from ray.tune.schedulers import AsyncHyperBandScheduler
        sched = AsyncHyperBandScheduler(metric="mean_loss", mode="min")
    elif scheduler == 'hb':
        from ray.tune.schedulers import HyperBandScheduler
        sched = HyperBandScheduler(metric="mean_loss", mode="min")
    elif algorithm == 'bohb' or scheduler == 'bohb':
        from ray.tune.schedulers import HyperBandForBOHB
        sched = HyperBandForBOHB(metric="mean_loss", mode="min")
    elif scheduler == 'msr':
        from ray.tune.schedulers import MedianStoppingRule
        sched = MedianStoppingRule(metric="mean_loss", mode="min")
    init_ray(
        address=getenv("ip_head"),
        redis_password=getenv('redis_password'),
    )
    analysis = tune.run(
        trainable,
        name='mlencrypt_research',
        config={
            "monitor": True,
            "env_config": {
                "wandb": {
                    "project": "mlencrypt-research",
                    "sync_tensorboard": True,
                },
            },
        },
        # resources_per_trial={"cpu": 1, "gpu": 3},
        local_dir='./ray_results',
        export_formats=['csv'],  # TODO: add other formats?
        num_samples=num_samples,
        loggers=[
            tune.logger.JsonLogger, tune.logger.CSVLogger,
            tune.logger.TBXLogger, WandbLogger
        ],
        search_alg=algo,
        scheduler=sched,
        queue_trials=True,
    )
    try:
        wandbsweep(analysis)
    except wandbCommError:
        # see https://docs.wandb.com/sweeps/ray-tune#feature-compatibility
        pass
    best_config = analysis.get_best_config(metric='mean_loss', mode='min')
    print(f"Best config: {best_config}")
    shutdown_ray()
Beispiel #26
0
def _test_xgboost(method='BlendSearch'):
    try:
        import ray
    except ImportError:
        return
    if method == 'BlendSearch':
        from flaml import tune
    else:
        from ray import tune
    search_space = {
        # You can mix constants with search space objects.
        "max_depth": tune.randint(1, 8) if method in [
            "BlendSearch", "BOHB", "Optuna"] else tune.randint(1, 9),
        "min_child_weight": tune.choice([1, 2, 3]),
        "subsample": tune.uniform(0.5, 1.0),
        "eta": tune.loguniform(1e-4, 1e-1)
    }
    max_iter = 10
    for num_samples in [256]:
        time_budget_s = 60 #None
        for n_cpu in [8]:
            start_time = time.time()
            ray.init(num_cpus=n_cpu, num_gpus=0)
            if method == 'BlendSearch':
                analysis = tune.run(
                    train_breast_cancer,
                    init_config={
                        "max_depth": 1,
                        "min_child_weight": 3,
                    },
                    cat_hp_cost={
                        "min_child_weight": [6, 3, 2],
                    },
                    metric="eval-logloss",
                    mode="min",
                    max_resource=max_iter,
                    min_resource=1,
                    report_intermediate_result=True,
                    # You can add "gpu": 0.1 to allocate GPUs
                    resources_per_trial={"cpu": 1},
                    config=search_space,
                    local_dir='logs/',
                    num_samples=num_samples*n_cpu,
                    time_budget_s=time_budget_s,
                    use_ray=True)
            else:
                if 'ASHA' == method:
                    algo = None
                elif 'BOHB' == method:
                    from ray.tune.schedulers import HyperBandForBOHB
                    from ray.tune.suggest.bohb import TuneBOHB
                    algo = TuneBOHB(max_concurrent=n_cpu)
                    scheduler = HyperBandForBOHB(max_t=max_iter)
                elif 'Optuna' == method:
                    from ray.tune.suggest.optuna import OptunaSearch
                    algo = OptunaSearch()
                elif 'CFO' == method:
                    from flaml import CFO
                    algo = CFO(points_to_evaluate=[{
                        "max_depth": 1,
                        "min_child_weight": 3,
                    }], cat_hp_cost={
                        "min_child_weight": [6, 3, 2],
                    })
                elif 'Dragonfly' == method:
                    from ray.tune.suggest.dragonfly import DragonflySearch
                    algo = DragonflySearch()
                elif 'SkOpt' == method:
                    from ray.tune.suggest.skopt import SkOptSearch
                    algo = SkOptSearch()
                elif 'Nevergrad' == method:
                    from ray.tune.suggest.nevergrad import NevergradSearch
                    import nevergrad as ng
                    algo = NevergradSearch(optimizer=ng.optimizers.OnePlusOne)
                elif 'ZOOpt' == method:
                    from ray.tune.suggest.zoopt import ZOOptSearch
                    algo = ZOOptSearch(budget=num_samples*n_cpu)
                elif 'Ax' == method:
                    from ray.tune.suggest.ax import AxSearch
                    algo = AxSearch()
                elif 'HyperOpt' == method:
                    from ray.tune.suggest.hyperopt import HyperOptSearch
                    algo = HyperOptSearch()
                    scheduler = None
                if method != 'BOHB':
                    from ray.tune.schedulers import ASHAScheduler
                    scheduler = ASHAScheduler(
                        max_t=max_iter,
                        grace_period=1)
                analysis = tune.run(
                    train_breast_cancer,
                    metric="eval-logloss",
                    mode="min",
                    # You can add "gpu": 0.1 to allocate GPUs
                    resources_per_trial={"cpu": 1},
                    config=search_space, local_dir='logs/',
                    num_samples=num_samples*n_cpu, time_budget_s=time_budget_s,
                    scheduler=scheduler, search_alg=algo)
            ray.shutdown()
            # # Load the best model checkpoint
            # best_bst = xgb.Booster()
            # best_bst.load_model(os.path.join(analysis.best_checkpoint,
            #  "model.xgb"))
            best_trial = analysis.get_best_trial("eval-logloss","min","all")
            accuracy = 1. - best_trial.metric_analysis["eval-error"]["min"]
            logloss = best_trial.metric_analysis["eval-logloss"]["min"]
            logger.info(f"method={method}")
            logger.info(f"n_samples={num_samples*n_cpu}")
            logger.info(f"time={time.time()-start_time}")
            logger.info(f"Best model eval loss: {logloss:.4f}")
            logger.info(f"Best model total accuracy: {accuracy:.4f}")
            logger.info(f"Best model parameters: {best_trial.config}")
Beispiel #27
0
    def testConvertBOHB(self):
        from ray.tune.suggest.bohb import TuneBOHB
        import ConfigSpace

        # Grid search not supported, should raise ValueError
        with self.assertRaises(ValueError):
            TuneBOHB.convert_search_space({"grid": tune.grid_search([0, 1])})

        config = {
            "a": tune.sample.Categorical([2, 3, 4]).uniform(),
            "b": {
                "x": tune.sample.Integer(0, 5).quantized(2),
                "y": 4,
                "z": tune.sample.Float(1e-4, 1e-2).loguniform()
            }
        }
        converted_config = TuneBOHB.convert_search_space(config)
        bohb_config = ConfigSpace.ConfigurationSpace()
        bohb_config.add_hyperparameters([
            ConfigSpace.CategoricalHyperparameter("a", [2, 3, 4]),
            ConfigSpace.UniformIntegerHyperparameter("b/x",
                                                     lower=0,
                                                     upper=4,
                                                     q=2),
            ConfigSpace.UniformFloatHyperparameter("b/z",
                                                   lower=1e-4,
                                                   upper=1e-2,
                                                   log=True)
        ])

        converted_config.seed(1234)
        bohb_config.seed(1234)

        searcher1 = TuneBOHB(space=converted_config, metric="a", mode="max")
        searcher2 = TuneBOHB(space=bohb_config, metric="a", mode="max")

        config1 = searcher1.suggest("0")
        config2 = searcher2.suggest("0")

        self.assertEqual(config1, config2)
        self.assertIn(config1["a"], [2, 3, 4])
        self.assertIn(config1["b"]["x"], list(range(5)))
        self.assertLess(1e-4, config1["b"]["z"])
        self.assertLess(config1["b"]["z"], 1e-2)

        searcher = TuneBOHB(metric="a", mode="max")
        analysis = tune.run(_mock_objective,
                            config=config,
                            search_alg=searcher,
                            num_samples=1)
        trial = analysis.trials[0]
        self.assertIn(trial.config["a"], [2, 3, 4])
        self.assertEqual(trial.config["b"]["y"], 4)

        mixed_config = {
            "a": tune.uniform(5, 6),
            "b": tune.uniform(8, 9)  # Cannot mix ConfigSpace and Dict
        }
        searcher = TuneBOHB(space=mixed_config, metric="a", mode="max")
        config = searcher.suggest("0")
        self.assertTrue(5 <= config["a"] <= 6)
        self.assertTrue(8 <= config["b"] <= 9)
    # Optional: Pass the parameter space yourself
    # config_space = CS.ConfigurationSpace()
    # config_space.add_hyperparameter(
    #     CS.UniformFloatHyperparameter("width", lower=0, upper=20))
    # config_space.add_hyperparameter(
    #     CS.UniformFloatHyperparameter("height", lower=-100, upper=100))
    # config_space.add_hyperparameter(
    #     CS.CategoricalHyperparameter(
    #         "activation", choices=["relu", "tanh"]))

    bohb_hyperband = HyperBandForBOHB(time_attr="training_iteration",
                                      max_t=100,
                                      reduction_factor=4)

    bohb_search = TuneBOHB(
        # space=config_space,  # If you want to set the space manually
        max_concurrent=4)

    analysis = tune.run(MyTrainableClass,
                        name="bohb_test",
                        config=config,
                        scheduler=bohb_hyperband,
                        search_alg=bohb_search,
                        num_samples=10,
                        stop={"training_iteration": 100},
                        metric="episode_reward_mean",
                        mode="max")

    print("Best hyperparameters found were: ", analysis.best_config)
Beispiel #29
0
    # Optional: Pass the parameter space yourself
    # config_space = CS.ConfigurationSpace()
    # config_space.add_hyperparameter(
    #     CS.UniformFloatHyperparameter("width", lower=0, upper=20))
    # config_space.add_hyperparameter(
    #     CS.UniformFloatHyperparameter("height", lower=-100, upper=100))
    # config_space.add_hyperparameter(
    #     CS.CategoricalHyperparameter(
    #         "activation", choices=["relu", "tanh"]))

    experiment_metrics = dict(metric="episode_reward_mean", mode="max")

    bohb_hyperband = HyperBandForBOHB(time_attr="training_iteration",
                                      max_t=100,
                                      reduction_factor=4,
                                      **experiment_metrics)

    bohb_search = TuneBOHB(
        # space=config_space,  # If you want to set the space manually
        max_concurrent=4,
        **experiment_metrics)

    tune.run(MyTrainableClass,
             name="bohb_test",
             config=config,
             scheduler=bohb_hyperband,
             search_alg=bohb_search,
             num_samples=10,
             stop={"training_iteration": 100})