155 lines
5.5 KiB
Python
155 lines
5.5 KiB
Python
#
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# OtterTune - gp.py
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#
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# Copyright (c) 2017-18, Carnegie Mellon University Database Group
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#
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'''
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Created on Feb 18, 2018
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@author: Bohan Zhang
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'''
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import numpy as np
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from scipy.spatial.distance import cdist as ed
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from scipy import special
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from analysis.gp_tf import GPRResult
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# numpy version of Gaussian Process Regression, not using Tensorflow
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class GPRNP(object):
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def __init__(self, length_scale=1.0, magnitude=1.0, max_train_size=7000,
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batch_size=3000, check_numerics=True, debug=False):
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assert np.isscalar(length_scale)
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assert np.isscalar(magnitude)
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assert length_scale > 0 and magnitude > 0
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self.length_scale = length_scale
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self.magnitude = magnitude
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self.max_train_size_ = max_train_size
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self.batch_size_ = batch_size
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self.check_numerics = check_numerics
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self.debug = debug
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self.X_train = None
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self.y_train = None
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self.K = None
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self.K_inv = None
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self.y_best = None
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self.ridge = None
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def __repr__(self):
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rep = ""
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for k, v in sorted(self.__dict__.items()):
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rep += "{} = {}\n".format(k, v)
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return rep
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def __str__(self):
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return self.__repr__()
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def _reset(self):
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self.X_train = None
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self.y_train = None
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self.K = None
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self.K_inv = None
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self.y_best = None
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def check_X_y(self, X, y):
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from sklearn.utils.validation import check_X_y
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if X.shape[0] > self.max_train_size_:
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raise Exception("X_train size cannot exceed {} ({})"
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.format(self.max_train_size_, X.shape[0]))
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return check_X_y(X, y, multi_output=True,
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allow_nd=True, y_numeric=True,
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estimator="GPRNP")
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def check_fitted(self):
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if self.X_train is None or self.y_train is None \
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or self.K is None:
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raise Exception("The model must be trained before making predictions!")
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@staticmethod
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def check_array(X):
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from sklearn.utils.validation import check_array
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return check_array(X, allow_nd=True, estimator="GPRNP")
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@staticmethod
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def check_output(X):
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finite_els = np.isfinite(X)
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if not np.all(finite_els):
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raise Exception("Input contains non-finite values: {}"
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.format(X[~finite_els]))
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def fit(self, X_train, y_train, ridge=1.0):
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self._reset()
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X_train, y_train = self.check_X_y(X_train, y_train)
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if X_train.ndim != 2 or y_train.ndim != 2:
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raise Exception("X_train or y_train should have 2 dimensions! X_dim:{}, y_dim:{}"
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.format(X_train.ndim, y_train.ndim))
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self.X_train = np.float32(X_train)
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self.y_train = np.float32(y_train)
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sample_size = self.X_train.shape[0]
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self.ridge = ridge
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if np.isscalar(ridge):
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ridge = np.ones(sample_size) * ridge
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assert isinstance(ridge, np.ndarray)
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assert ridge.ndim == 1
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K = self.magnitude * np.exp(-ed(self.X_train, self.X_train) / self.length_scale) \
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+ np.diag(ridge)
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K_inv = np.linalg.inv(K)
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self.K = K
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self.K_inv = K_inv
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self.y_best = np.min(y_train)
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return self
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def predict(self, X_test):
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self.check_fitted()
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if X_test.ndim != 2:
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raise Exception("X_test should have 2 dimensions! X_dim:{}"
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.format(X_test.ndim))
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X_test = np.float32(GPRNP.check_array(X_test))
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test_size = X_test.shape[0]
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arr_offset = 0
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length_scale = self.length_scale
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yhats = np.zeros([test_size, 1])
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sigmas = np.zeros([test_size, 1])
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eips = np.zeros([test_size, 1])
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while arr_offset < test_size:
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if arr_offset + self.batch_size_ > test_size:
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end_offset = test_size
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else:
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end_offset = arr_offset + self.batch_size_
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xt_ = X_test[arr_offset:end_offset]
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K2 = self.magnitude * np.exp(-ed(self.X_train, xt_) / length_scale)
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K3 = self.magnitude * np.exp(-ed(xt_, xt_) / length_scale)
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K2_trans = np.transpose(K2)
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yhat = np.matmul(K2_trans, np.matmul(self.K_inv, self.y_train))
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xt_size = K3.shape[0]
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ridge = self.ridge
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if np.isscalar(ridge):
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ridge = np.ones(xt_size) * ridge
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sigma = np.sqrt(np.diag(K3 - np.matmul(K2_trans, np.matmul(self.K_inv, K2))
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+ np.diag(ridge))).reshape(xt_.shape[0], 1)
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u = (self.y_best - yhat) / sigma
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phi1 = 0.5 * special.erf(u / np.sqrt(2.0)) + 0.5
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phi2 = (1.0 / np.sqrt(2.0 * np.pi)) * np.exp(np.square(u) * (-0.5))
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eip = sigma * (u * phi1 + phi2)
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yhats[arr_offset:end_offset] = yhat
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sigmas[arr_offset:end_offset] = sigma
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eips[arr_offset:end_offset] = eip
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arr_offset = end_offset
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GPRNP.check_output(yhats)
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GPRNP.check_output(sigmas)
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return GPRResult(yhats, sigmas)
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def get_params(self, deep=True):
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return {"length_scale": self.length_scale,
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"magnitude": self.magnitude,
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"X_train": self.X_train,
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"y_train": self.y_train,
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"K": self.K,
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"K_inv": self.K_inv}
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def set_params(self, **parameters):
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for param, val in list(parameters.items()):
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setattr(self, param, val)
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return self
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