예제 #1
0
    def test_dist_info_sym_wrong_input(self):
        env = TfEnv(DummyBoxEnv(obs_dim=(1, ), action_dim=(1, )))

        obs_ph = tf.placeholder(tf.float32,
                                shape=(None, None,
                                       env.observation_space.flat_dim))

        with mock.patch(('garage.tf.policies.'
                         'gaussian_lstm_policy_with_model.GaussianLSTMModel'),
                        new=SimpleGaussianLSTMModel):
            policy = GaussianLSTMPolicyWithModel(env_spec=env.spec,
                                                 state_include_action=True)

            policy.reset()
            obs = env.reset()

            policy.dist_info_sym(
                obs_var=obs_ph,
                state_info_vars={'prev_action': np.zeros((3, 1, 1))},
                name='p2_sym')
        # observation batch size = 2 but prev_action batch size = 3
        with self.assertRaises(tf.errors.InvalidArgumentError):
            self.sess.run(
                policy.model.networks['p2_sym'].input,
                feed_dict={obs_ph: [[obs.flatten()], [obs.flatten()]]})
    def test_dist_info_sym_include_action(self, obs_dim, action_dim,
                                          hidden_dim):
        env = TfEnv(DummyBoxEnv(obs_dim=obs_dim, action_dim=action_dim))

        obs_ph = tf.placeholder(
            tf.float32, shape=(None, None, env.observation_space.flat_dim))

        with mock.patch(('garage.tf.policies.'
                         'gaussian_lstm_policy_with_model.GaussianLSTMModel'),
                        new=SimpleGaussianLSTMModel):
            policy = GaussianLSTMPolicyWithModel(
                env_spec=env.spec, state_include_action=True)

            policy.reset()
            obs = env.reset()
            dist_sym = policy.dist_info_sym(
                obs_var=obs_ph,
                state_info_vars={'prev_action': np.zeros((2, 1) + action_dim)},
                name='p2_sym')
        dist = self.sess.run(
            dist_sym, feed_dict={obs_ph: [[obs.flatten()], [obs.flatten()]]})

        assert np.array_equal(dist['mean'], np.full((2, 1) + action_dim, 0.5))
        assert np.array_equal(dist['log_std'], np.full((2, 1) + action_dim,
                                                       0.5))
class TestGaussianLSTMPolicyWithModelTransit(TfGraphTestCase):
    def setup_method(self):
        super().setup_method()
        with mock.patch('tensorflow.random.normal') as mock_rand:
            mock_rand.return_value = 0.5
            env = TfEnv(DummyBoxEnv(obs_dim=(1, ), action_dim=(1, )))
            self.default_initializer = tf.constant_initializer(1)
            self.default_hidden_nonlinearity = tf.nn.tanh
            self.default_recurrent_nonlinearity = tf.nn.sigmoid
            self.default_output_nonlinearity = None
            self.time_step = 1

            self.policy1 = GaussianLSTMPolicy(
                env_spec=env.spec,
                hidden_dim=4,
                hidden_nonlinearity=self.default_hidden_nonlinearity,
                recurrent_nonlinearity=self.default_recurrent_nonlinearity,
                recurrent_w_x_init=self.default_initializer,
                recurrent_w_h_init=self.default_initializer,
                output_nonlinearity=self.default_output_nonlinearity,
                output_w_init=self.default_initializer,
                state_include_action=True,
                name='P1')
            self.policy2 = GaussianLSTMPolicy(
                env_spec=env.spec,
                hidden_dim=4,
                hidden_nonlinearity=self.default_hidden_nonlinearity,
                recurrent_nonlinearity=self.default_recurrent_nonlinearity,
                recurrent_w_x_init=self.default_initializer,
                recurrent_w_h_init=self.default_initializer,
                output_nonlinearity=self.default_output_nonlinearity,
                output_w_init=tf.constant_initializer(2),
                state_include_action=True,
                name='P2')

            self.sess.run(tf.global_variables_initializer())

            self.policy3 = GaussianLSTMPolicyWithModel(
                env_spec=env.spec,
                hidden_dim=4,
                hidden_nonlinearity=self.default_hidden_nonlinearity,
                hidden_w_init=self.default_initializer,
                recurrent_nonlinearity=self.default_recurrent_nonlinearity,
                recurrent_w_init=self.default_initializer,
                output_nonlinearity=self.default_output_nonlinearity,
                output_w_init=self.default_initializer,
                state_include_action=True,
                name='P3')
            self.policy4 = GaussianLSTMPolicyWithModel(
                env_spec=env.spec,
                hidden_dim=4,
                hidden_nonlinearity=self.default_hidden_nonlinearity,
                hidden_w_init=self.default_initializer,
                recurrent_nonlinearity=self.default_recurrent_nonlinearity,
                recurrent_w_init=self.default_initializer,
                output_nonlinearity=self.default_output_nonlinearity,
                output_w_init=tf.constant_initializer(2),
                state_include_action=True,
                name='P4')

            self.policy1.reset()
            self.policy2.reset()
            self.policy3.reset()
            self.policy4.reset()
            self.obs = [env.reset()]
            self.obs = np.concatenate(
                [self.obs for _ in range(self.time_step)], axis=0)

            self.obs_ph = tf.placeholder(
                tf.float32, shape=(None, None, env.observation_space.flat_dim))
            self.action_ph = tf.placeholder(tf.float32,
                                            shape=(None, None,
                                                   env.action_space.flat_dim))

            self.dist1_sym = self.policy1.dist_info_sym(
                obs_var=self.obs_ph,
                state_info_vars={
                    'prev_action': np.zeros((2, self.time_step, 1))
                },
                name='p1_sym')
            self.dist2_sym = self.policy2.dist_info_sym(
                obs_var=self.obs_ph,
                state_info_vars={
                    'prev_action': np.zeros((2, self.time_step, 1))
                },
                name='p2_sym')
            self.dist3_sym = self.policy3.dist_info_sym(
                obs_var=self.obs_ph,
                state_info_vars={
                    'prev_action': np.zeros((2, self.time_step, 1))
                },
                name='p3_sym')
            self.dist4_sym = self.policy4.dist_info_sym(
                obs_var=self.obs_ph,
                state_info_vars={
                    'prev_action': np.zeros((2, self.time_step, 1))
                },
                name='p4_sym')

    def test_dist_info_sym_output(self):
        # batch size = 2
        dist1 = self.sess.run(self.dist1_sym,
                              feed_dict={self.obs_ph: [self.obs, self.obs]})
        dist2 = self.sess.run(self.dist2_sym,
                              feed_dict={self.obs_ph: [self.obs, self.obs]})
        dist3 = self.sess.run(self.dist3_sym,
                              feed_dict={self.obs_ph: [self.obs, self.obs]})
        dist4 = self.sess.run(self.dist4_sym,
                              feed_dict={self.obs_ph: [self.obs, self.obs]})

        assert np.array_equal(dist1['mean'], dist3['mean'])
        assert np.array_equal(dist1['log_std'], dist3['log_std'])
        assert np.array_equal(dist2['mean'], dist4['mean'])
        assert np.array_equal(dist2['log_std'], dist4['log_std'])

    @mock.patch('numpy.random.normal')
    def test_get_action(self, mock_rand):
        mock_rand.return_value = 0.5

        action1, agent_info1 = self.policy1.get_action(self.obs)
        action2, agent_info2 = self.policy2.get_action(self.obs)
        action3, agent_info3 = self.policy3.get_action(self.obs)
        action4, agent_info4 = self.policy4.get_action(self.obs)

        assert np.array_equal(action1, action3)
        assert np.array_equal(action2, action4)
        assert np.array_equal(agent_info1['mean'], agent_info3['mean'])
        assert np.array_equal(agent_info1['log_std'], agent_info3['log_std'])
        assert np.array_equal(agent_info2['mean'], agent_info4['mean'])
        assert np.array_equal(agent_info2['log_std'], agent_info4['log_std'])

        actions1, agent_infos1 = self.policy1.get_actions([self.obs])
        actions2, agent_infos2 = self.policy2.get_actions([self.obs])
        actions3, agent_infos3 = self.policy3.get_actions([self.obs])
        actions4, agent_infos4 = self.policy4.get_actions([self.obs])

        assert np.array_equal(actions1, actions3)
        assert np.array_equal(actions2, actions4)
        assert np.array_equal(agent_infos1['mean'], agent_infos3['mean'])
        assert np.array_equal(agent_infos1['log_std'], agent_infos3['log_std'])
        assert np.array_equal(agent_infos2['mean'], agent_infos4['mean'])
        assert np.array_equal(agent_infos2['log_std'], agent_infos4['log_std'])

    def test_kl_sym(self):
        kl_diff_sym1 = self.policy1.distribution.kl_sym(
            self.dist1_sym, self.dist2_sym)
        objective1 = tf.reduce_mean(kl_diff_sym1)

        kl_func = tensor_utils.compile_function([self.obs_ph], objective1)
        kl1 = kl_func([self.obs, self.obs])

        kl_diff_sym2 = self.policy3.distribution.kl_sym(
            self.dist3_sym, self.dist4_sym)
        objective2 = tf.reduce_mean(kl_diff_sym2)

        kl_func = tensor_utils.compile_function([self.obs_ph], objective2)
        kl2 = kl_func([self.obs, self.obs])

        assert np.array_equal(kl1, kl2)

    def test_log_likehihood_sym(self):
        log_prob_sym1 = self.policy1.distribution.log_likelihood_sym(
            self.action_ph, self.dist1_sym)
        log_prob_func = tensor_utils.compile_function(
            [self.obs_ph, self.action_ph], log_prob_sym1)
        log_prob1 = log_prob_func([self.obs, self.obs],
                                  np.ones((2, self.time_step, 1)))

        log_prob_sym2 = self.policy3.distribution.log_likelihood_sym(
            self.action_ph, self.dist3_sym)
        log_prob_func2 = tensor_utils.compile_function(
            [self.obs_ph, self.action_ph], log_prob_sym2)
        log_prob2 = log_prob_func2([self.obs, self.obs],
                                   np.ones((2, self.time_step, 1)))
        assert np.array_equal(log_prob1, log_prob2)

        log_prob_sym1 = self.policy2.distribution.log_likelihood_sym(
            self.action_ph, self.dist2_sym)
        log_prob_func = tensor_utils.compile_function(
            [self.obs_ph, self.action_ph], log_prob_sym1)
        log_prob1 = log_prob_func([self.obs, self.obs],
                                  np.ones((2, self.time_step, 1)))

        log_prob_sym2 = self.policy4.distribution.log_likelihood_sym(
            self.action_ph, self.dist4_sym)
        log_prob_func2 = tensor_utils.compile_function(
            [self.obs_ph, self.action_ph], log_prob_sym2)
        log_prob2 = log_prob_func2([self.obs, self.obs],
                                   np.ones((2, self.time_step, 1)))
        assert np.array_equal(log_prob1, log_prob2)

    def test_policy_entropy_sym(self):
        entropy_sym1 = self.policy1.distribution.entropy_sym(
            self.dist1_sym, name='entropy_sym1')
        entropy_func = tensor_utils.compile_function([self.obs_ph],
                                                     entropy_sym1)
        entropy1 = entropy_func([self.obs, self.obs])

        entropy_sym2 = self.policy3.distribution.entropy_sym(
            self.dist3_sym, name='entropy_sym1')
        entropy_func = tensor_utils.compile_function([self.obs_ph],
                                                     entropy_sym2)
        entropy2 = entropy_func([self.obs, self.obs])
        assert np.array_equal(entropy1, entropy2)

    def test_likelihood_ratio_sym(self):
        likelihood_ratio_sym1 = self.policy1.distribution.likelihood_ratio_sym(
            self.action_ph,
            self.dist1_sym,
            self.dist2_sym,
            name='li_ratio_sym1')
        likelihood_ratio_func = tensor_utils.compile_function(
            [self.action_ph, self.obs_ph], likelihood_ratio_sym1)
        likelihood_ratio1 = likelihood_ratio_func(np.ones((2, 1, 1)),
                                                  [self.obs, self.obs])

        likelihood_ratio_sym2 = self.policy3.distribution.likelihood_ratio_sym(
            self.action_ph,
            self.dist3_sym,
            self.dist4_sym,
            name='li_ratio_sym2')
        likelihood_ratio_func = tensor_utils.compile_function(
            [self.action_ph, self.obs_ph], likelihood_ratio_sym2)
        likelihood_ratio2 = likelihood_ratio_func(np.ones((2, 1, 1)),
                                                  [self.obs, self.obs])

        assert np.array_equal(likelihood_ratio1, likelihood_ratio2)