def _RunOptimizationImpl(self):
     # Look for the minimum max_delta that results in a successful comparison
     # for each possible edge_threshold/max_diff combination.
     for edge_threshold in xrange(self._args.max_edge_threshold,
                                  self._args.min_edge_threshold,
                                  -1 * self._args.edge_threshold_step):
         should_continue = True
         for max_diff in xrange(self._args.min_max_diff,
                                self._args.max_max_diff,
                                self._args.max_diff_step):
             for max_delta in xrange(self._args.min_delta_threshold,
                                     self._args.max_delta_threshold,
                                     self._args.delta_threshold_step):
                 parameters = parameter_set.ParameterSet(
                     max_diff, max_delta, edge_threshold)
                 success, _, _ = self._RunComparisonForParameters(
                     parameters)
                 if success:
                     print 'Found good parameters %s' % parameters
                     should_continue = False
                     break
                 logging.info('Found bad parameters %s', parameters)
             # Increasing the max_diff for a given edge_threshold once we've found
             # a good max_delta won't give us any new information, so go on to the
             # next edge_threshold.
             if not should_continue:
                 break
Exemplo n.º 2
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  def _AdjacentParameters(self, starting_parameters):
    max_diff = starting_parameters.max_diff
    delta_threshold = starting_parameters.delta_threshold
    edge_threshold = starting_parameters.edge_threshold

    max_diff_step = self._args.max_diff_step
    delta_threshold_step = self._args.delta_threshold_step
    edge_threshold_step = self._args.edge_threshold_step

    max_diffs = [
        max(self._args.min_max_diff, max_diff - max_diff_step), max_diff,
        min(self._args.max_max_diff, max_diff + max_diff_step)
    ]
    delta_thresholds = [
        max(self._args.min_delta_threshold,
            delta_threshold - delta_threshold_step), delta_threshold,
        min(self._args.max_delta_threshold,
            delta_threshold + delta_threshold_step)
    ]
    edge_thresholds = [
        max(self._args.min_edge_threshold,
            edge_threshold - edge_threshold_step), edge_threshold,
        min(self._args.max_edge_threshold, edge_threshold + edge_threshold_step)
    ]
    for combo in itertools.product(max_diffs, delta_thresholds,
                                   edge_thresholds):
      adjacent = parameter_set.ParameterSet(combo[0], combo[1], combo[2])
      if adjacent != starting_parameters:
        yield adjacent
Exemplo n.º 3
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def p1b1_parameter_set():
    """Utility function to encapsulate ParameterSet definition"""

    ps = prs.ParameterSet()

    ps["activation"] = prs.DiscreteParameter(activation)
    ps["batch_size"] = prs.NumericListParameter(batch_size)
    ps["dense"] = prs.DiscreteParameter(dense)
    ps["drop"] = prs.NumericParameter(0.0, 0.9)
    ps["epochs"] = prs.IntegerParameter(10, 20)  #100, 200)
    ps["latent_dim"] = prs.NumericListParameter(latent_dim)
    ps["learning_rate"] = prs.NumericParameter(0.00001, 0.1)
    ps["model"] = prs.DiscreteParameter(model)
    ps["optimizer"] = prs.DiscreteParameter(optimizer)
    ps["residual"] = prs.DiscreteParameter(residual)
    ps["reduce_lr"] = prs.DiscreteParameter(reduce_lr)
    ps["warmup_lr"] = prs.DiscreteParameter(warmup_lr)

    #    # switching batch_size to NumericList to enforce integer validation
    #    ps.add(prs.DiscreteParameter("activation", activation))
    #    ps.add(prs.NumericListParameter("batch_size", batch_size))
    #    ps.add(prs.DiscreteParameter("dense", dense))
    #    ps.add(prs.NumericParameter("drop", 0.0, 0.9))
    #    ps.add(prs.IntegerParameter("epochs",  10, 20)) #100, 200))
    #    ps.add(prs.NumericListParameter("latent_dim", latent_dim))
    #    ps.add(prs.NumericParameter("learning_rate", 0.00001, 0.1))
    #    ps.add(prs.DiscreteParameter("model", model))
    #    ps.add(prs.DiscreteParameter("optimizer", optimizer))
    #    ps.add(prs.DiscreteParameter("residual", residual))
    #    ps.add(prs.DiscreteParameter("reduce_lr", reduce_lr))
    #    ps.add(prs.DiscreteParameter("warmup_lr", warmup_lr))

    return ps
  def _CreateParameterSet(self, value):
    """Creates a parameter_set.ParameterSet to test.

    Args:
      value: The value to set the variable parameter to.

    Returns:
      A parameter_set.ParameterSet with the variable parameter set to |value|
      and the other parameters set to their fixed values.
    """
    if self._unlocked_parameter == self.UNLOCKED_PARAM_MAX_DIFF:
      return parameter_set.ParameterSet(value, self._args.min_delta_threshold,
                                        self._args.min_edge_threshold)
    elif self._unlocked_parameter == self.UNLOCKED_PARAM_DELTA_THRESHOLD:
      return parameter_set.ParameterSet(self._args.min_max_diff, value,
                                        self._args.min_edge_threshold)
    else:
      return parameter_set.ParameterSet(self._args.min_max_diff,
                                        self._args.min_delta_threshold, value)
Exemplo n.º 5
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def p3b1_parameter_set():
    """Utility function to encapsulate ParameterSet definition"""

    ps = prs.ParameterSet()

    # switching batch_size to NumericList to enforce integer validation
    #ps.add(prs.DiscreteParameter("batch_size", batch_size))
    ps.add(prs.NumericListParameter("batch_size", batch_size))
    ps.add(prs.IntegerParameter("epochs", 5, 50))
    #ps.add(prs.DiscreteParameter("activation", activation))
    #ps.add(prs.DiscreteParameter("optimizer", optimizer))
    ps.add(prs.NumericParameter("dropout", 0.0, 0.9))
    ps.add(prs.NumericParameter("learning_rate", 0.00001, 0.1))
    ps.add(prs.DiscreteParameter("shared_nnet_spec", shared_nnet_spec))
    ps.add(prs.DiscreteParameter("ind_nnet_spec", ind_nnet_spec))

    return ps
Exemplo n.º 6
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def p1b1_parameter_set():
    """Utility function to encapsulate ParameterSet definition"""

    ps = prs.ParameterSet()

    # batch_size is NumericList to enforce integer validation
    ps["activation"] = prs.DiscreteParameter(activation)
    ps["batch_size"] = prs.NumericListParameter(batch_size)
    ps["dense"] = prs.DiscreteParameter(dense)
    ps["drop"] = prs.NumericParameter(0.0, 0.9)
    # limit maximum number of epcohs for demonstration purposes
    ps["epochs"] = prs.IntegerParameter(10, 20)  #100, 200)
    ps["latent_dim"] = prs.NumericListParameter(latent_dim)
    ps["learning_rate"] = prs.NumericParameter(0.00001, 0.1)
    ps["model"] = prs.DiscreteParameter(model)
    ps["optimizer"] = prs.DiscreteParameter(optimizer)
    ps["residual"] = prs.DiscreteParameter(residual)
    ps["reduce_lr"] = prs.DiscreteParameter(reduce_lr)
    ps["warmup_lr"] = prs.DiscreteParameter(warmup_lr)

    return ps
Exemplo n.º 7
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 def __init__(self, data_df, X_columns, target, factors=[], 
              prefix_sep="|"):
     
     dfc_set = set(data_df.columns)
     xcol_set = set(X_columns)
     factor_set = set(factors)
     
     assert target in dfc_set, "Target column must be in dataframe"
     assert xcol_set.issubset(dfc_set), "X_columns must be in dataframe's columns"
     assert factor_set.issubset(dfc_set), "Factors must be in dataframe's columns"
     #assert set(factors).issubset(set(X_columns)), "Factors should be listed in X_columns"
     
     self.data = data_df
     self.factors = factors
     
     xcol_set = xcol_set | factor_set    # set union
     xcol_set.discard(target)
     
     # n.b. set is not a hashable type so make it a list
     X = data_df[list(xcol_set)]
     y = data_df[target]
     
     # Create auxiliary dataframe with dummy-coded indicators 
     Xd = pd.get_dummies(X,
                         columns=factors,
                         prefix_sep=prefix_sep) if factors else X
         
     continuous_columns = []
     factor_columns = defaultdict(list)
     factor_values = defaultdict(list)
     
     factor_objects = {}
     
     for i, name in enumerate(Xd.columns):
         n = name.split(prefix_sep)
         n0 = n[0]
         if n0 in factors:
             factor_columns[n0].append(i)
             factor_values[n0].append(prefix_sep.join(n[1:]))
         else:
             continuous_columns.append(i)
             
     # TODO: create a new parameter set, just for the factors
     ps_factor = prs.ParameterSet()
     for name, values in factor_values.items():
         #ps_factor.add(prs.DiscreteParameter(name, values))
         ps_factor[name] = prs.DiscreteParameter(values)
         columns = factor_columns[name]
         factor_objects[name] = Factor(name, columns, values)
 
     #self.n_continuous = len(continuous_columns)
     self.continuous_columns = continuous_columns
     self.factor_columns = factor_columns
     self.parameter_set = ps_factor
     self.X = X
     self.Xd = Xd
     self.y = y
     
     # TODO: consider leaving these till later, and using hasattr to check
     self.gpr_ec = None
     self.gpr_mc = None
     self.gpr_uc = None
# =============================================================================
# ParameterSet generated initial sample grid used to train model
# creates candidate parameter dictionaries after model is trained
# see parameter_set for a more complete parameter set matching R
# =============================================================================
batch_size = [16, 32, 64, 128, 256, 512]
#activation = ["softmax", "elu", "softplus", "softsign", "relu", "tanh", "sigmoid", "hard_sigmoid", "linear"]
dense = [[500, 100, 50], [1000, 500, 100, 50], [2000, 1000, 500, 100, 50],
         [2000, 1000, 1000, 500, 100, 50],
         [2000, 1000, 1000, 1000, 500, 100, 50]]
#optimizer = ["adam", "sgd", "rmsprop", "adagrad", "adadelta","adamax","nadam"]
conv = [[50, 50, 50, 50, 50, 1], [25, 25, 25, 25, 25, 1],
        [64, 32, 16, 32, 64, 1], [100, 100, 100, 100, 100, 1],
        [32, 20, 16, 32, 10, 1]]

ps = prs.ParameterSet()

ps.add(prs.DiscreteParameter("batch_size", batch_size))
ps.add(prs.IntegerParameter("epochs", 5, 100))
#ps.add(prs.DiscreteParameter("activation", activation))
ps.add(prs.DiscreteParameter("dense", dense))
#ps.add(prs.DiscreteParameter("optimizer", optimizer))
ps.add(prs.NumericParameter("drop", 0.0, 0.9))
ps.add(prs.NumericParameter("learning_rate", 0.00001, 0.1))
ps.add(prs.DiscreteParameter("conv", conv))
# TODO: since dense and conv will be dummy-coded, ensure that all possible
# category values are present in the parameter set

# =============================================================================
# DATA
# =============================================================================
Exemplo n.º 9
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 def _GetMostPermissiveParameters(self):
     return parameter_set.ParameterSet(self._args.max_max_diff,
                                       self._args.max_delta_threshold,
                                       self._args.min_edge_threshold)