# coding=utf-8
import numpy as np
import scipy.optimize
import six
[ドキュメント]class batch(object):
"""
basis class for batch learning
"""
def __init__(self, gp, config):
"""
Parameters
----------
gp : physbo.gp.core.model object
config: physbo.misc.set_config object
"""
self.gp = gp
self.config = config
[ドキュメント] def run(self, X, t):
"""
Performing optimization using the L-BFGS-B algorithm
Parameters
----------
X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
Returns
-------
numpy.ndarray
The solution of the optimization.
"""
batch_size = self.config.learning.batch_size
sub_X, sub_t = self.gp.sub_sampling(X, t, batch_size)
if self.config.learning.num_init_params_search != 0:
is_init_params_search = True
else:
is_init_params_search = False
if is_init_params_search:
params = self.init_params_search(sub_X, sub_t)
else:
params = np.copy(self.gp.params)
params = self.one_run(params, sub_X, sub_t)
return params
[ドキュメント] def one_run(self, params, X, t, max_iter=None):
"""
Parameters
----------
params: numpy.ndarray
Initial guess for optimization.
Array of real elements of size (n,), where ‘n’ is the number of independent variables.
X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
max_iter: int
Maximum number of iterations to perform.
Returns
-------
numpy.ndarray
The solution of the optimization.
"""
# is_disp: Set to True to print convergence messages.
is_disp = True
if max_iter is None:
is_disp = self.config.learning.is_disp
max_iter = int(self.config.learning.max_iter)
args = (X, t)
bound = self.gp.get_params_bound()
res = scipy.optimize.minimize(
fun=self.gp.eval_marlik,
args=args,
x0=params,
method="L-BFGS-B",
jac=self.gp.get_grad_marlik,
bounds=bound,
options={"disp": is_disp, "maxiter": max_iter},
)
return res.x
[ドキュメント] def init_params_search(self, X, t):
"""
Parameters
----------
X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
Returns
-------
numpy.ndarray
The parameters which give the minimum marginal likelihood.
"""
num_init_params_search = self.config.learning.num_init_params_search
max_iter = int(self.config.learning.max_iter_init_params_search)
min_params = np.zeros(self.gp.num_params)
min_marlik = np.inf
for i in range(num_init_params_search):
params = self.gp.get_cand_params(X, t)
params = self.one_run(params, X, t, max_iter)
marlik = self.gp.eval_marlik(params, X, t)
if min_marlik > marlik:
min_marlik = marlik
min_params = params
# print 'minimum marginal likelihood = ', min_marlik
return min_params
[ドキュメント]class online(object):
"""
base class for online learning
"""
def __init__(self, gp, config):
"""
Parameters
----------
gp : model (gp.core.model)
config: set_config (misc.set_config)
"""
self.gp = gp
self.config = config
self.num_iter = 0
[ドキュメント] def run(self, X, t):
"""
Run initial search and hyper parameter running.
Parameters
----------
X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
Returns
-------
numpy.ndarray
The solution of the optimization.
"""
if self.config.learning.num_init_params_search != 0:
is_init_params_search = True
else:
is_init_params_search = False
if is_init_params_search:
print("Start the initial hyper parameter searching ...")
params = self.init_params_search(X, t)
print("Done\n")
else:
params = np.copy(self.params)
print("Start the hyper parameter learning ...")
params = self.one_run(params, X, t)
print("Done\n")
return params
[ドキュメント] def one_run(self, params, X, t, max_epoch=None):
"""
Parameters
----------
params: numpy.ndarray
Parameters for optimization.
Array of real elements of size (n,), where ‘n’ is the number of independent variables.
X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
max_epoch: int
Maximum candidate epochs
Returns
-------
numpy.ndarray
The solution of the optimization.
"""
num_data = X.shape[0]
is_disp = False
batch_size = self.config.learning.batch_size
if batch_size > num_data:
batch_size = num_data
if max_epoch is None:
max_epoch = self.config.learning.max_epoch
is_disp = self.config.learning.is_disp
num_disp = self.config.learning.num_disp
eval_size = self.config.learning.eval_size
eval_X, eval_t = self.gp.sub_sampling(X, t, eval_size)
timing = range(0, max_epoch, int(np.floor(max_epoch / num_disp)))
temp = 0
for num_epoch in range(0, max_epoch):
perm = np.random.permutation(num_data)
if is_disp and temp < num_disp and num_epoch == timing[temp]:
self.disp_marlik(params, eval_X, eval_t, num_epoch)
temp += 1
for n in six.moves.range(0, num_data, batch_size):
tmp_index = perm[n : n + batch_size]
if len(tmp_index) == batch_size:
self.num_iter += 1
subX = X[tmp_index, :]
subt = t[tmp_index]
params += self.get_one_update(params, subX, subt)
if is_disp:
self.disp_marlik(params, eval_X, eval_t, num_epoch + 1)
self.reset()
return params
[ドキュメント] def disp_marlik(self, params, eval_X, eval_t, num_epoch=None):
"""
Displaying marginal likelihood
Parameters
----------
params: numpy.ndarray
Parameters for optimization.
Array of real elements of size (n,), where ‘n’ is the number of independent variables.
eval_X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
eval_t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
num_epoch: int
Number of epochs
Returns
-------
"""
marlik = self.gp.eval_marlik(params, eval_X, eval_t)
if num_epoch is not None:
print(num_epoch, end=" ")
print("-th epoch", end=" ")
print("marginal likelihood", marlik)
[ドキュメント] def init_params_search(self, X, t):
"""
Initial parameter searchs
Parameters
----------
X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
Returns
-------
numpy.ndarray
The parameter which gives the minimum likelihood.
"""
num_init_params_search = self.config.learning.num_init_params_search
is_disp = self.config.learning.is_disp
max_epoch = self.config.learning.max_epoch_init_params_search
eval_size = self.config.learning.eval_size
eval_X, eval_t = self.gp.sub_sampling(X, t, eval_size)
min_params = np.zeros(self.gp.num_params)
min_marlik = np.inf
for i in range(num_init_params_search):
params = self.gp.get_cand_params(X, t)
params = self.one_run(params, X, t, max_epoch)
marlik = self.gp.eval_marlik(params, eval_X, eval_t)
if min_marlik > marlik:
min_marlik = marlik
min_params = params
# print 'minimum marginal likelihood = ', min_marlik
return min_params
[ドキュメント] def get_one_update(self, params, X, t):
raise NotImplementedError
[ドキュメント]class adam(online):
""" default """
def __init__(self, gp, config):
"""
Parameters
----------
gp : physbo.gp.core.model object
config: physbo.misc.set_config object
"""
super(adam, self).__init__(gp, config)
self.alpha = self.config.learning.alpha
self.beta = self.config.learning.beta
self.gamma = self.config.learning.gamma
self.epsilon = self.config.learning.epsilon
self.m = np.zeros(self.gp.num_params)
self.v = np.zeros(self.gp.num_params)
[ドキュメント] def reset(self):
self.m = np.zeros(self.gp.num_params)
self.v = np.zeros(self.gp.num_params)
self.num_iter = 0
[ドキュメント] def get_one_update(self, params, X, t):
"""
Parameters
----------
params: numpy.ndarray
Parameters for optimization.
Array of real elements of size (n,), where ‘n’ is the number of independent variables.
X: numpy.ndarray
N x d dimensional matrix. Each row of X denotes the d-dimensional feature vector of search candidate.
t: numpy.ndarray
N-dimensional vector that represents the corresponding negative energy of search candidates.
Returns
-------
"""
grad = self.gp.get_grad_marlik(params, X, t)
self.m = self.m * self.beta + grad * (1 - self.beta)
self.v = self.v * self.gamma + grad ** 2 * (1 - self.gamma)
hat_m = self.m / (1 - self.beta ** (self.num_iter))
hat_v = self.v / (1 - self.gamma ** (self.num_iter))
return -self.alpha * hat_m / (np.sqrt(hat_v) + self.epsilon)