GPy/GPy/testing/gpy_kernels_state_space_tests.py

# -*- coding: utf-8 -*-
# Copyright (c) 2015, Alex Grigorevskiy
# Licensed under the BSD 3-clause license (see LICENSE.txt)
"""
Testing state space related functions.
"""
import unittest
import numpy as np
import GPy
import GPy.models.state_space_model as SS_model
from .state_space_main_tests import generate_x_points, generate_sine_data, \
    generate_linear_data, generate_brownian_data, generate_linear_plus_sin

#from state_space_main_tests import generate_x_points, generate_sine_data, \
#    generate_linear_data, generate_brownian_data, generate_linear_plus_sin

class StateSpaceKernelsTests(np.testing.TestCase):
    def setUp(self):
        pass

    def run_for_model(self, X, Y, ss_kernel, kalman_filter_type = 'regular',
                      use_cython=False, check_gradients=True,
                      optimize=True, optimize_max_iters=250, predict_X=None,
                      compare_with_GP=True, gp_kernel=None,
                      mean_compare_decimal=10, var_compare_decimal=7):

        m1  = SS_model.StateSpace(X,Y, ss_kernel,
                                kalman_filter_type=kalman_filter_type,
                                use_cython=use_cython)

        m1.likelihood[:] = Y.var()/100.

        if check_gradients:
            self.assertTrue(m1.checkgrad())

        if 1:#optimize:
            m1.optimize(optimizer='lbfgsb', max_iters=1)

        if compare_with_GP and (predict_X is None):
            predict_X = X

        self.assertTrue(compare_with_GP)
        if compare_with_GP:
            m2  = GPy.models.GPRegression(X,Y, gp_kernel)

            m2[:] = m1[:]

            if (predict_X is not None):
                x_pred_reg_1 = m1.predict(predict_X)
                x_quant_reg_1 = m1.predict_quantiles(predict_X)

            x_pred_reg_2 = m2.predict(predict_X)
            x_quant_reg_2 = m2.predict_quantiles(predict_X)

            np.testing.assert_array_almost_equal(x_pred_reg_1[0], x_pred_reg_2[0], mean_compare_decimal)
            np.testing.assert_array_almost_equal(x_pred_reg_1[1], x_pred_reg_2[1], var_compare_decimal)
            np.testing.assert_array_almost_equal(x_quant_reg_1[0], x_quant_reg_2[0], mean_compare_decimal)
            np.testing.assert_array_almost_equal(x_quant_reg_1[1], x_quant_reg_2[1], mean_compare_decimal)
            np.testing.assert_array_almost_equal(m1.gradient, m2.gradient, var_compare_decimal)
            np.testing.assert_almost_equal(m1.log_likelihood(), m2.log_likelihood(), var_compare_decimal)


    def test_Matern32_kernel(self,):
        np.random.seed(234) # seed the random number generator
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=10.0, noise_var=2.0,
                        plot = False, points_num=50, x_interval = (0, 20), random=True)
        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_Matern32(1,active_dims=[0,])
        gp_kernel = GPy.kern.Matern32(1,active_dims=[0,])

        self.run_for_model(X, Y, ss_kernel, check_gradients=True,
                           predict_X=X,
                           compare_with_GP=True,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=5, var_compare_decimal=5)

    def test_Matern52_kernel(self,):
        np.random.seed(234) # seed the random number generator
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=10.0, noise_var=2.0,
                        plot = False, points_num=50, x_interval = (0, 20), random=True)
        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_Matern52(1,active_dims=[0,])
        gp_kernel = GPy.kern.Matern52(1,active_dims=[0,])

        self.run_for_model(X, Y, ss_kernel, check_gradients=True,
                           optimize = True, predict_X=X,
                           compare_with_GP=True, gp_kernel=gp_kernel,
                           mean_compare_decimal=5, var_compare_decimal=5)

    def test_RBF_kernel(self,):
        np.random.seed(234) # seed the random number generator
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=10.0, noise_var=2.0,
                        plot = False, points_num=50, x_interval = (0, 20), random=True)
        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_RBF(1, 110., 1.5, active_dims=[0,])
        gp_kernel = GPy.kern.RBF(1, 110., 1.5, active_dims=[0,])
        
        self.run_for_model(X, Y, ss_kernel, check_gradients=True,
                           predict_X=X,
                           gp_kernel=gp_kernel,
                           optimize_max_iters=1000,
                           mean_compare_decimal=2, var_compare_decimal=1)

    def test_periodic_kernel(self,):
        np.random.seed(322) # seed the random number generator
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=10.0, noise_var=2.0,
                        plot = False, points_num=50, x_interval = (0, 20), random=True)
        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_StdPeriodic(1,active_dims=[0,])
        ss_kernel.lengthscale.constrain_bounded(0.27, 1000)
        ss_kernel.period.constrain_bounded(0.17, 100)

        gp_kernel = GPy.kern.StdPeriodic(1,active_dims=[0,])
        gp_kernel.lengthscale.constrain_bounded(0.27, 1000)
        gp_kernel.period.constrain_bounded(0.17, 100)

        self.run_for_model(X, Y, ss_kernel, check_gradients=True,
                           predict_X=X,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=3, var_compare_decimal=3)

    def test_quasi_periodic_kernel(self,):
        np.random.seed(329) # seed the random number generator
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=10.0, noise_var=2.0,
                        plot = False, points_num=50, x_interval = (0, 20), random=True)
        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_Matern32(1)*GPy.kern.sde_StdPeriodic(1,active_dims=[0,])
        ss_kernel.std_periodic.lengthscale.constrain_bounded(0.25, 1000)
        ss_kernel.std_periodic.period.constrain_bounded(0.15, 100)

        gp_kernel = GPy.kern.Matern32(1)*GPy.kern.StdPeriodic(1,active_dims=[0,])
        gp_kernel.std_periodic.lengthscale.constrain_bounded(0.25, 1000)
        gp_kernel.std_periodic.period.constrain_bounded(0.15, 100)

        self.run_for_model(X, Y, ss_kernel, check_gradients=True,
                            predict_X=X,
                            gp_kernel=gp_kernel,
                            mean_compare_decimal=1, var_compare_decimal=2)

    def test_linear_kernel(self,):

        np.random.seed(234) # seed the random number generator
        (X,Y) = generate_linear_data(x_points=None, tangent=2.0, add_term=20.0, noise_var=2.0,
                    plot = False, points_num=50, x_interval = (0, 20), random=True)

        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_Linear(1,X,active_dims=[0,]) + GPy.kern.sde_Bias(1, active_dims=[0,])
        gp_kernel = GPy.kern.Linear(1, active_dims=[0,]) + GPy.kern.Bias(1, active_dims=[0,])

        self.run_for_model(X, Y, ss_kernel, check_gradients= False,
                           predict_X=X,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=5, var_compare_decimal=5)

    def test_brownian_kernel(self,):
        np.random.seed(234) # seed the random number generator
        (X,Y) = generate_brownian_data(x_points=None, kernel_var=2.0, noise_var = 0.1,
                    plot = False, points_num=50, x_interval = (0, 20), random=True)

        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_Brownian()
        gp_kernel = GPy.kern.Brownian()

        self.run_for_model(X, Y, ss_kernel, check_gradients=True,
                            predict_X=X,
                            gp_kernel=gp_kernel,
                            mean_compare_decimal=4, var_compare_decimal=4)

    def test_exponential_kernel(self,):
        np.random.seed(12345) # seed the random number generator
        (X,Y) = generate_linear_data(x_points=None, tangent=1.0, add_term=20.0, noise_var=2.0,
                    plot = False, points_num=10, x_interval = (0, 20), random=True)

        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        ss_kernel = GPy.kern.sde_Exponential(1, Y.var(), X.ptp()/2., active_dims=[0,])
        gp_kernel = GPy.kern.Exponential(1, Y.var(), X.ptp()/2., active_dims=[0,])

        Y -= Y.mean()

        self.run_for_model(X, Y, ss_kernel, check_gradients=True,
                      predict_X=X,
                      gp_kernel=gp_kernel,
                      optimize_max_iters=1000,
                      mean_compare_decimal=2, var_compare_decimal=2)

    def test_kernel_addition(self,):
        #np.random.seed(329) # seed the random number generator
        np.random.seed(333)
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=5.0, noise_var=2.0,
                        plot = False, points_num=100, x_interval = (0, 40), random=True)

        (X1,Y1) = generate_linear_data(x_points=X, tangent=1.0, add_term=20.0, noise_var=0.0,
                    plot = False, points_num=100, x_interval = (0, 40), random=True)

        # Sine data <-
        Y = Y + Y1
        Y -= Y.mean()

        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        def get_new_kernels():
            ss_kernel = GPy.kern.sde_Linear(1,X,variances=1) + GPy.kern.sde_StdPeriodic(1,period=5.0, variance=300, lengthscale=3., active_dims=[0,])
            #ss_kernel.std_periodic.lengthscale.constrain_bounded(0.25, 1000)
            #ss_kernel.std_periodic.period.constrain_bounded(3, 8)

            gp_kernel = GPy.kern.Linear(1,variances=1) + GPy.kern.StdPeriodic(1,period=5.0, variance=300, lengthscale=3., active_dims=[0,])
            #gp_kernel.std_periodic.lengthscale.constrain_bounded(0.25, 1000)
            #gp_kernel.std_periodic.period.constrain_bounded(3, 8)

            return ss_kernel, gp_kernel

        # Cython is available only with svd.
        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X, Y, ss_kernel, kalman_filter_type = 'svd',
                           use_cython=True, optimize_max_iters=10, check_gradients=False,
                           predict_X=X,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=5, var_compare_decimal=5)

        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X, Y, ss_kernel, kalman_filter_type = 'regular',
                           use_cython=False, optimize_max_iters=10, check_gradients=True,
                           predict_X=X,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=5, var_compare_decimal=5)

        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X, Y, ss_kernel, kalman_filter_type = 'svd',
                           use_cython=False, optimize_max_iters=10, check_gradients=False,
                           predict_X=X,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=5, var_compare_decimal=5)


    def test_kernel_multiplication(self,):
        np.random.seed(329) # seed the random number generator
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=10.0, noise_var=2.0,
                        plot = False, points_num=50, x_interval = (0, 20), random=True)

        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)

        def get_new_kernels():
            ss_kernel = GPy.kern.sde_Matern32(1)*GPy.kern.sde_Matern52(1)
            gp_kernel = GPy.kern.Matern32(1)*GPy.kern.sde_Matern52(1)

            return ss_kernel, gp_kernel

        ss_kernel, gp_kernel = get_new_kernels()

        #import ipdb;ipdb.set_trace()
        self.run_for_model(X, Y, ss_kernel, kalman_filter_type = 'svd',
                           use_cython=True, optimize_max_iters=10, check_gradients=True,
                            predict_X=X,
                            gp_kernel=gp_kernel,
                            mean_compare_decimal=2, var_compare_decimal=2)

        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X, Y, ss_kernel, kalman_filter_type = 'regular',
                           use_cython=False, optimize_max_iters=10, check_gradients=True,
                            predict_X=X,
                            gp_kernel=gp_kernel,
                            mean_compare_decimal=2, var_compare_decimal=2)

        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X, Y, ss_kernel, kalman_filter_type = 'svd',
                           use_cython=False, optimize_max_iters=10, check_gradients=True,
                            predict_X=X,
                            gp_kernel=gp_kernel,
                            mean_compare_decimal=2, var_compare_decimal=2)

    def test_forecast(self,):
        """
        Test time-series forecasting.
        """

        # Generate data ->
        np.random.seed(339) # seed the random number generator
        #import pdb; pdb.set_trace()
        (X,Y) = generate_sine_data(x_points=None, sin_period=5.0, sin_ampl=5.0, noise_var=2.0,
                        plot = False, points_num=100, x_interval = (0, 40), random=True)

        (X1,Y1) = generate_linear_data(x_points=X, tangent=1.0, add_term=20.0, noise_var=0.0,
                    plot = False, points_num=100, x_interval = (0, 40), random=True)

        Y = Y + Y1

        X_train = X[X <= 20]
        Y_train = Y[X <= 20]
        X_test = X[X > 20]
        Y_test = Y[X > 20]

        X.shape = (X.shape[0],1); Y.shape = (Y.shape[0],1)
        X_train.shape = (X_train.shape[0],1); Y_train.shape = (Y_train.shape[0],1)
        X_test.shape = (X_test.shape[0],1); Y_test.shape = (Y_test.shape[0],1)
        # Generate data <-

        #import pdb; pdb.set_trace()

        def get_new_kernels():
            periodic_kernel = GPy.kern.StdPeriodic(1,active_dims=[0,])
            gp_kernel = GPy.kern.Linear(1, active_dims=[0,]) + GPy.kern.Bias(1, active_dims=[0,]) + periodic_kernel
            gp_kernel.std_periodic.lengthscale.constrain_bounded(0.25, 1000)
            gp_kernel.std_periodic.period.constrain_bounded(0.15, 100)

            periodic_kernel = GPy.kern.sde_StdPeriodic(1,active_dims=[0,])
            ss_kernel = GPy.kern.sde_Linear(1,X,active_dims=[0,]) + \
                GPy.kern.sde_Bias(1, active_dims=[0,]) + periodic_kernel

            ss_kernel.std_periodic.lengthscale.constrain_bounded(0.25, 1000)
            ss_kernel.std_periodic.period.constrain_bounded(0.15, 100)

            return ss_kernel, gp_kernel

        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X_train, Y_train, ss_kernel, kalman_filter_type = 'regular',
                           use_cython=False, optimize_max_iters=30, check_gradients=True,
                           predict_X=X_test,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=2, var_compare_decimal=2)


        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X_train, Y_train, ss_kernel, kalman_filter_type = 'svd',
                           use_cython=False, optimize_max_iters=30, check_gradients=False,
                           predict_X=X_test,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=2, var_compare_decimal=2)

        ss_kernel, gp_kernel = get_new_kernels()
        self.run_for_model(X_train, Y_train, ss_kernel, kalman_filter_type = 'svd',
                           use_cython=True, optimize_max_iters=30, check_gradients=False,
                           predict_X=X_test,
                           gp_kernel=gp_kernel,
                           mean_compare_decimal=2, var_compare_decimal=2)

if __name__ == "__main__":
    print("Running state-space inference tests...")
    unittest.main()

    #tt = StateSpaceKernelsTests('test_periodic_kernel')
    #import pdb; pdb.set_trace()
    #tt.test_Matern32_kernel()
    #tt.test_Matern52_kernel()
    #tt.test_RBF_kernel()
    #tt.test_periodic_kernel()
    #tt.test_quasi_periodic_kernel()
    #tt.test_linear_kernel()
    #tt.test_brownian_kernel()
    #tt.test_exponential_kernel()
    #tt.test_kernel_addition()
    #tt.test_kernel_multiplication()
    #tt.test_forecast()