"""Monitor and influence the optimization procedure via callbacks. Callbacks are callables which are invoked after each iteration of the optimizer and are passed the results "so far". Callbacks can monitor progress, or stop the optimization early by returning `True`. """ try: from collections.abc import Callable except ImportError: from collections.abc import Callable import os from time import time import numpy as np from skopt.utils import dump, load def check_callback(callback): """Check if callback is a callable or a list of callables.""" if callback is not None: if isinstance(callback, Callable): return [callback] elif isinstance(callback, list) and all( [isinstance(c, Callable) for c in callback] ): return callback else: raise ValueError( "callback should be either a callable or " "a list of callables." ) else: return [] class VerboseCallback: """Callback to control the verbosity. Parameters ---------- n_init : int, optional Number of points provided by the user which are yet to be evaluated. This is equal to `len(x0)` when `y0` is None n_random : int, optional Number of points randomly chosen. n_total : int Total number of func calls. Attributes ---------- iter_no : int Number of iterations of the optimization routine. """ def __init__(self, n_total, n_init=0, n_random=0): self.n_init = n_init self.n_random = n_random self.n_total = n_total self.iter_no = 1 self._start_time = time() self._print_info(start=True) def _print_info(self, start=True): iter_no = self.iter_no if start: status = "started" eval_status = "Evaluating function" search_status = "Searching for the next optimal point." else: status = "ended" eval_status = "Evaluation done" search_status = "Search finished for the next optimal point." if iter_no <= self.n_init: print( "Iteration No: %d %s. %s at provided point." % (iter_no, status, eval_status) ) elif self.n_init < iter_no <= (self.n_random + self.n_init): print( "Iteration No: %d %s. %s at random point." % (iter_no, status, eval_status) ) else: print("Iteration No: %d %s. %s" % (iter_no, status, search_status)) def __call__(self, res): """ Parameters ---------- res : `OptimizeResult`, scipy object The optimization as a OptimizeResult object. """ time_taken = time() - self._start_time self._print_info(start=False) curr_y = res.func_vals[-1] curr_min = res.fun print("Time taken: %0.4f" % time_taken) print("Function value obtained: %0.4f" % curr_y) print("Current minimum: %0.4f" % curr_min) self.iter_no += 1 if self.iter_no <= self.n_total: self._print_info(start=True) self._start_time = time() class TimerCallback: """Log the elapsed time between each iteration of the minimization loop. The time for each iteration is stored in the `iter_time` attribute which you can inspect after the minimization has completed. Attributes ---------- iter_time : list, shape (n_iter,) `iter_time[i-1]` gives the time taken to complete iteration `i` """ def __init__(self): self._time = time() self.iter_time = [] def __call__(self, res): """ Parameters ---------- res : `OptimizeResult`, scipy object The optimization as a OptimizeResult object. """ elapsed_time = time() - self._time self.iter_time.append(elapsed_time) self._time = time() class EarlyStopper: """Decide to continue or not given the results so far. The optimization procedure will be stopped if the callback returns True. """ def __call__(self, result): """ Parameters ---------- result : `OptimizeResult`, scipy object The optimization as a OptimizeResult object. """ return self._criterion(result) def _criterion(self, result): """Compute the decision to stop or not. Classes inheriting from `EarlyStop` should use this method to implement their decision logic. Parameters ---------- result : `OptimizeResult`, scipy object The optimization as a OptimizeResult object. Returns ------- decision : boolean or None Return True/False if the criterion can make a decision or `None` if there is not enough data yet to make a decision. """ raise NotImplementedError( "The _criterion method should be implemented" " by subclasses of EarlyStopper." ) class DeltaXStopper(EarlyStopper): """Stop the optimization when ``|x1 - x2| < delta`` If the last two positions at which the objective has been evaluated are less than `delta` apart stop the optimization procedure. """ def __init__(self, delta): super(EarlyStopper, self).__init__() self.delta = delta def _criterion(self, result): if len(result.x_iters) >= 2: return ( result.space.distance(result.x_iters[-2], result.x_iters[-1]) < self.delta ) else: return None class DeltaYStopper(EarlyStopper): """Stop the optimization if the `n_best` minima are within `delta` Stop the optimizer if the absolute difference between the `n_best` objective values is less than `delta`. """ def __init__(self, delta, n_best=5): super(EarlyStopper, self).__init__() self.delta = delta self.n_best = n_best def _criterion(self, result): if len(result.func_vals) >= self.n_best: func_vals = np.sort(result.func_vals) worst = func_vals[self.n_best - 1] best = func_vals[0] # worst is always larger, so no need for abs() return worst - best < self.delta else: return None class HollowIterationsStopper(EarlyStopper): """Stop if the improvement over the last n iterations is below a threshold.""" def __init__(self, n_iterations, threshold=0): super().__init__() self.n_iterations = n_iterations self.threshold = abs(threshold) def _criterion(self, result): if len(result.func_vals) <= self.n_iterations: return False cummin = np.minimum.accumulate(result.func_vals) return cummin[-self.n_iterations - 1] - cummin[-1] <= self.threshold class DeadlineStopper(EarlyStopper): """Stop the optimization before running out of a fixed budget of time. Attributes ---------- iter_time : list, shape (n_iter,) `iter_time[i-1]` gives the time taken to complete iteration `i` Parameters ---------- total_time : float fixed budget of time (seconds) that the optimization must finish within. """ def __init__(self, total_time): super().__init__() self._time = time() self.iter_time = [] self.total_time = total_time def _criterion(self, result): elapsed_time = time() - self._time self.iter_time.append(elapsed_time) self._time = time() if result.x_iters: time_remaining = self.total_time - np.sum(self.iter_time) return time_remaining <= np.max(self.iter_time) else: return None class StdStopper(EarlyStopper): """Stop the optimization when the standard deviation of the Gaussian process is lower than the threshold. Paper: automatic-termination-for-hyperparameter-optimization """ def __init__(self, threshold: float, log_interval=10) -> None: super(EarlyStopper, self).__init__() self.threshold = threshold self.log_interval = log_interval def _criterion(self, result) -> bool: y_train_std_ = [] for model in result.models: y_train_std_.append(model.y_train_std_) if len(y_train_std_) == 0: return False if len(y_train_std_) % self.log_interval == 0: print( "num_models:", len(y_train_std_), "min_std:", min(y_train_std_), "max_std:", max(y_train_std_), ) return min(y_train_std_) <= self.threshold class ThresholdStopper(EarlyStopper): """Stop the optimization when the objective value is lower than the given threshold.""" def __init__(self, threshold: float) -> None: super(EarlyStopper, self).__init__() self.threshold = threshold def _criterion(self, result) -> bool: return np.any([val <= self.threshold for val in result.func_vals]) class CheckpointSaver: """Save current state after each iteration with :class:`skopt.dump`. Allows to re- use previously computed function evaluations. Examples -------- >>> import skopt >>> def obj_fun(x): ... return x[0]**2 >>> checkpoint_callback = skopt.callbacks.CheckpointSaver("./result.pkl") >>> skopt.gp_minimize(obj_fun, [(-2, 2)], n_calls=10, ... callback=[checkpoint_callback]) # doctest: +SKIP >>> # when re-using stored results. >>> checkpoint_callback = skopt.callbacks.CheckpointSaver("./result.pkl") >>> skopt.gp_minimize(obj_fun, [(-2, 2)], n_calls=10, ... callback=[checkpoint_callback] ... **checkpoint_callback.load()) # doctest: +SKIP Parameters ---------- checkpoint_path : string location where checkpoint will be saved to; dump_options : string options to pass on to `skopt.dump`, like `compress=9` """ def __init__(self, checkpoint_path, **dump_options): self.checkpoint_path = checkpoint_path self.dump_options = dump_options def __call__(self, res): """ Parameters ---------- res : `OptimizeResult`, scipy object The optimization as a OptimizeResult object. """ dump(res, self.checkpoint_path, **self.dump_options) def load(self): """Loads from disk previously evaluated points. Returns ------- Dict with previous evaluations and their latest surrogate state. """ if os.path.exists(self.checkpoint_path): result = load(self.checkpoint_path) return { 'x0': result.x_iters, 'y0': result.func_vals, 'base_estimator': result.models[-1] if result.models else None, } return {}