def __init__()

in robosumo/policy_zoo/policy.py [0:0]


    def __init__(self, scope, *, ob_space, ac_space, hiddens,
                 reuse=False, normalize=False):
        self.recurrent = True
        self.normalized = normalize

        with tf.variable_scope(scope, reuse=reuse):
            self.scope = tf.get_variable_scope().name

            self.observation_ph = tf.placeholder(
                tf.float32, [None, None] + list(ob_space.shape),
                name="observation")
            self.taken_action_ph = tf.placeholder(
                tf.float32, [None, None, ac_space.shape[0]],
                name="taken_action")
            self.stochastic_ph = tf.placeholder(tf.bool, (), name="stochastic")

            if self.normalized:
                if self.normalized != 'ob':
                    self.ret_rms = RunningMeanStd(scope="retfilter")
                self.ob_rms = RunningMeanStd(
                    scope="obsfilter",
                    shape=ob_space.shape)

            # Observation filtering
            obz = self.observation_ph
            if self.normalized:
                obz = tf.clip_by_value((self.observation_ph - self.ob_rms.mean) / self.ob_rms.std, -5.0, 5.0)

            # Embedding
            last_out = obz
            for hidden in hiddens[:-1]:
                last_out = tf.contrib.layers.fully_connected(last_out, hidden)

            self.zero_state = []
            self.state_in_ph = []
            self.state_out = []

            # Value
            cell = tf.contrib.rnn.BasicLSTMCell(hiddens[-1], reuse=reuse)
            size = cell.state_size
            self.zero_state.append(np.zeros(size.c, dtype=np.float32))
            self.zero_state.append(np.zeros(size.h, dtype=np.float32))
            self.state_in_ph.append(
                tf.placeholder(tf.float32, [None, size.c], name="lstmv_c"))
            self.state_in_ph.append(
                tf.placeholder(tf.float32, [None, size.h], name="lstmv_h"))
            initial_state = tf.contrib.rnn.LSTMStateTuple(
                self.state_in_ph[-2], self.state_in_ph[-1])
            last_out, state_out = tf.nn.dynamic_rnn(
                cell, last_out, initial_state=initial_state, scope="lstmv")
            self.state_out.append(state_out)

            self.vpredz = tf.contrib.layers.fully_connected(last_out, 1, activation_fn=None)[:, :, 0]
            self.vpred = self.vpredz
            if self.normalized and self.normalized != 'ob':
                self.vpred = self.vpredz * self.ret_rms.std + self.ret_rms.mean

            # Policy
            last_out = obz
            for hidden in hiddens[:-1]:
                last_out = tf.contrib.layers.fully_connected(last_out, hidden)
            cell = tf.contrib.rnn.BasicLSTMCell(hiddens[-1], reuse=reuse)
            size = cell.state_size
            self.zero_state.append(np.zeros(size.c, dtype=np.float32))
            self.zero_state.append(np.zeros(size.h, dtype=np.float32))
            self.state_in_ph.append(
                tf.placeholder(tf.float32, [None, size.c], name="lstmp_c"))
            self.state_in_ph.append(
                tf.placeholder(tf.float32, [None, size.h], name="lstmp_h"))
            initial_state = tf.contrib.rnn.LSTMStateTuple(
                self.state_in_ph[-2], self.state_in_ph[-1])
            last_out, state_out = tf.nn.dynamic_rnn(
                cell, last_out, initial_state=initial_state, scope="lstmp")
            self.state_out.append(state_out)

            mean = tf.contrib.layers.fully_connected(
                last_out, ac_space.shape[0], activation_fn=None)
            logstd = tf.get_variable(
                name="logstd",
                shape=[1, ac_space.shape[0]],
                initializer=tf.zeros_initializer())

            self.pd = DiagonalGaussian(mean, logstd)
            self.sampled_action = switch(
                self.stochastic_ph, self.pd.sample(), self.pd.mode())

            self.zero_state = np.array(self.zero_state)
            self.state_in_ph = tuple(self.state_in_ph)
            self.state = self.zero_state