431 lines
16 KiB
Python
431 lines
16 KiB
Python
import multiprocessing
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import os
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import platform
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from functools import partial
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import numpy as np
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import tensorflow as tf
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from baselines.common.tf_util import normc_initializer
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from mpi4py import MPI
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import tensorflow_probability as tfp
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import os
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import numpy as np
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tfd = tfp.distributions
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layers = tf.keras.layers
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def bcast_tf_vars_from_root(sess, vars):
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"""
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Send the root node's parameters to every worker.
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Arguments:
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sess: the TensorFlow session.
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vars: all parameter variables including optimizer's
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"""
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rank = MPI.COMM_WORLD.Get_rank()
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for var in vars:
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if rank == 0:
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MPI.COMM_WORLD.bcast(sess.run(var))
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else:
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sess.run(tf.assign(var, MPI.COMM_WORLD.bcast(None)))
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def get_mean_and_std(array):
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comm = MPI.COMM_WORLD
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task_id, num_tasks = comm.Get_rank(), comm.Get_size()
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local_mean = np.array(np.mean(array))
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sum_of_means = np.zeros((), dtype=np.float32)
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comm.Allreduce(local_mean, sum_of_means, op=MPI.SUM)
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mean = sum_of_means / num_tasks
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n_array = array - mean
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sqs = n_array ** 2
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local_mean = np.array(np.mean(sqs))
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sum_of_means = np.zeros((), dtype=np.float32)
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comm.Allreduce(local_mean, sum_of_means, op=MPI.SUM)
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var = sum_of_means / num_tasks
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std = var ** 0.5
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return mean, std
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def guess_available_gpus(n_gpus=None):
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if n_gpus is not None:
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return list(range(n_gpus))
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if 'CUDA_VISIBLE_DEVICES' in os.environ:
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cuda_visible_divices = os.environ['CUDA_VISIBLE_DEVICES']
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cuda_visible_divices = cuda_visible_divices.split(',')
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return [int(n) for n in cuda_visible_divices]
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nvidia_dir = '/proc/driver/nvidia/gpus/'
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if os.path.exists(nvidia_dir):
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n_gpus = len(os.listdir(nvidia_dir))
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return list(range(n_gpus))
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raise Exception("Couldn't guess the available gpus on this machine")
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def setup_mpi_gpus():
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"""
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Set CUDA_VISIBLE_DEVICES using MPI.
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"""
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available_gpus = guess_available_gpus()
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node_id = platform.node()
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nodes_ordered_by_rank = MPI.COMM_WORLD.allgather(node_id)
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processes_outranked_on_this_node = [n for n in nodes_ordered_by_rank[:MPI.COMM_WORLD.Get_rank()] if n == node_id]
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local_rank = len(processes_outranked_on_this_node)
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os.environ['CUDA_VISIBLE_DEVICES'] = str(available_gpus[local_rank])
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def guess_available_cpus():
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return int(multiprocessing.cpu_count())
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def setup_tensorflow_session():
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num_cpu = guess_available_cpus()
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tf_config = tf.ConfigProto(
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inter_op_parallelism_threads=num_cpu,
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intra_op_parallelism_threads=num_cpu
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)
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tf_config.gpu_options.allow_growth = True
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return tf.Session(config=tf_config)
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def random_agent_ob_mean_std(env, nsteps=10000):
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ob = np.asarray(env.reset())
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if MPI.COMM_WORLD.Get_rank() == 0:
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obs = [ob]
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for _ in range(nsteps):
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ac = env.action_space.sample()
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ob, _, done, _ = env.step(ac)
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if done:
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ob = env.reset()
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obs.append(np.asarray(ob))
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mean = np.mean(obs, 0).astype(np.float32)
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std = np.std(obs, 0).mean().astype(np.float32)
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else:
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mean = np.empty(shape=ob.shape, dtype=np.float32)
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std = np.empty(shape=(), dtype=np.float32)
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MPI.COMM_WORLD.Bcast(mean, root=0)
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MPI.COMM_WORLD.Bcast(std, root=0)
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return mean, std
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def layernorm(x):
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m, v = tf.nn.moments(x, -1, keep_dims=True)
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return (x - m) / (tf.sqrt(v) + 1e-8)
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getsess = tf.get_default_session
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fc = partial(tf.layers.dense, kernel_initializer=normc_initializer(1.))
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activ = tf.nn.relu
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def flatten_two_dims(x):
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return tf.reshape(x, [-1] + x.get_shape().as_list()[2:])
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def unflatten_first_dim(x, sh):
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return tf.reshape(x, [sh[0], sh[1]] + x.get_shape().as_list()[1:])
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def add_pos_bias(x):
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with tf.variable_scope(name_or_scope=None, default_name="pos_bias"):
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b = tf.get_variable(name="pos_bias", shape=[1] + x.get_shape().as_list()[1:], dtype=tf.float32,
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initializer=tf.zeros_initializer())
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return x + b
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def small_convnet(x, nl, feat_dim, last_nl, layernormalize, batchnorm=False):
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# nl=512, feat_dim=None, last_nl=0, layernormalize=0, batchnorm=False
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bn = tf.layers.batch_normalization if batchnorm else lambda x: x
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x = bn(tf.layers.conv2d(x, filters=32, kernel_size=8, strides=(4, 4), activation=nl))
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x = bn(tf.layers.conv2d(x, filters=64, kernel_size=4, strides=(2, 2), activation=nl))
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x = bn(tf.layers.conv2d(x, filters=64, kernel_size=3, strides=(1, 1), activation=nl))
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x = tf.reshape(x, (-1, np.prod(x.get_shape().as_list()[1:])))
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x = bn(fc(x, units=feat_dim, activation=None))
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if last_nl is not None:
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x = last_nl(x)
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if layernormalize:
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x = layernorm(x)
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return x
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# new add
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class SmallConv(tf.keras.Model):
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def __init__(self, feat_dim, name=None):
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super(SmallConv, self).__init__(name=name)
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self.conv1 = layers.Conv2D(filters=32, kernel_size=8, strides=(4, 4), activation=tf.nn.leaky_relu)
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self.conv2 = layers.Conv2D(filters=64, kernel_size=4, strides=(2, 2), activation=tf.nn.leaky_relu)
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self.conv3 = layers.Conv2D(filters=64, kernel_size=3, strides=(1, 1), activation=tf.nn.leaky_relu)
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self.fc = layers.Dense(units=feat_dim, activation=None)
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def call(self, x):
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x = self.conv1(x)
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x = self.conv2(x)
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x = self.conv3(x)
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x = tf.reshape(x, (-1, np.prod(x.get_shape().as_list()[1:])))
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x = self.fc(x)
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return x
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# new add
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class ResBlock(tf.keras.Model):
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def __init__(self, hidsize):
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super(ResBlock, self).__init__()
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self.hidsize = hidsize
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self.dense1 = layers.Dense(hidsize, activation=tf.nn.leaky_relu)
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self.dense2 = layers.Dense(hidsize, activation=None)
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def call(self, xs):
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x, a = xs
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res = self.dense1(tf.concat([x, a], axis=-1))
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res = self.dense2(tf.concat([res, a], axis=-1))
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assert x.get_shape().as_list()[-1] == self.hidsize and res.get_shape().as_list()[-1] == self.hidsize
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return x + res
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# new add
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class TransitionNetwork(tf.keras.Model):
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def __init__(self, hidsize=256, name=None):
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super(TransitionNetwork, self).__init__(name=name)
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self.hidsize = hidsize
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self.dense1 = layers.Dense(hidsize, activation=tf.nn.leaky_relu)
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self.residual_block1 = ResBlock(hidsize)
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self.residual_block2 = ResBlock(hidsize)
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self.dense2 = layers.Dense(hidsize, activation=None)
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def call(self, xs):
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s, a = xs
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sh = tf.shape(a) # sh=(None,None,4)
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assert len(s.get_shape().as_list()) == 3 and s.get_shape().as_list()[-1] in [512, 256]
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assert len(a.get_shape().as_list()) == 3
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x = flatten_two_dims(s) # shape=(None,512)
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a = flatten_two_dims(a) # shape=(None,4)
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#
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x = self.dense1(tf.concat([x, a], axis=-1)) # (None, 256)
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x = self.residual_block1([x, a]) # (None, 256)
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x = self.residual_block2([x, a]) # (None, 256)
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x = self.dense2(tf.concat([x, a], axis=-1)) # (None, 256)
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x = unflatten_first_dim(x, sh) # shape=(None, None, 256)
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return x
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class GenerativeNetworkGaussianFix(tf.keras.Model):
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def __init__(self, hidsize=256, outsize=512, name=None):
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super(GenerativeNetworkGaussianFix, self).__init__(name=name)
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self.outsize = outsize
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self.dense1 = layers.Dense(hidsize, activation=tf.nn.leaky_relu)
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self.dense2 = layers.Dense(outsize, activation=tf.nn.leaky_relu)
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self.var_single = tf.Variable(1.0, trainable=True)
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self.residual_block1 = tf.keras.Sequential([
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layers.Dense(hidsize, activation=tf.nn.leaky_relu), # 256
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layers.Dense(hidsize, activation=None)
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])
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self.residual_block2 = tf.keras.Sequential([
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layers.Dense(hidsize, activation=tf.nn.leaky_relu), # 256
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layers.Dense(hidsize, activation=None)
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])
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self.residual_block3 = tf.keras.Sequential([
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layers.Dense(outsize, activation=tf.nn.leaky_relu), # 512
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layers.Dense(outsize, activation=None)
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])
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def call(self, z):
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sh = tf.shape(z) # z, sh=(None,None,128)
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assert z.get_shape().as_list()[-1] == 128 and len(z.get_shape().as_list()) == 3
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z = flatten_two_dims(z) # shape=(None,128)
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x = self.dense1(z) # (None, 256)
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x = x + self.residual_block1(x) # (None, 256)
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x = x + self.residual_block2(x) # (None, 256)
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# variance
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var_tile = tf.tile(tf.expand_dims(tf.expand_dims(self.var_single, axis=0), axis=0), [16*128, self.outsize])
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# mean
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x = self.dense2(x) # (None, 512)
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x = x + self.residual_block3(x) # (None, 512) mean
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# concat and return
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x = tf.concat([x, var_tile], axis=-1) # (None, 1024)
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x = unflatten_first_dim(x, sh) # shape=(None, None, 1024)
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return x
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class GenerativeNetworkGaussian(tf.keras.Model):
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def __init__(self, hidsize=256, outsize=512, name=None):
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super(GenerativeNetworkGaussian, self).__init__(name=name)
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self.dense1 = layers.Dense(hidsize, activation=tf.nn.leaky_relu)
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self.dense2 = layers.Dense(outsize, activation=tf.nn.leaky_relu)
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self.dense3 = layers.Dense(outsize*2, activation=tf.nn.leaky_relu)
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self.residual_block1 = tf.keras.Sequential([
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layers.Dense(hidsize, activation=tf.nn.leaky_relu), # 256
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layers.Dense(hidsize, activation=None)
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])
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self.residual_block2 = tf.keras.Sequential([
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layers.Dense(hidsize, activation=tf.nn.leaky_relu), # 256
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layers.Dense(hidsize, activation=None)
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])
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self.residual_block3 = tf.keras.Sequential([
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layers.Dense(outsize, activation=tf.nn.leaky_relu), # 512
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layers.Dense(outsize, activation=None)
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])
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def call(self, z):
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sh = tf.shape(z) # z, sh=(None,None,128)
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assert z.get_shape().as_list()[-1] == 128 and len(z.get_shape().as_list()) == 3
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z = flatten_two_dims(z) # shape=(None,128)
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x = self.dense1(z) # (None, 256)
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x = x + self.residual_block1(x) # (None, 256)
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x = x + self.residual_block2(x) # (None, 256)
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x = self.dense2(x) # (None, 512)
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x = x + self.residual_block3(x) # (None, 512)
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x = self.dense3(x) # (None, 1024)
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x = unflatten_first_dim(x, sh) # shape=(None, None, 1024)
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return x
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class ProjectionHead(tf.keras.Model):
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def __init__(self, name=None):
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super(ProjectionHead, self).__init__(name=name)
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self.dense1 = layers.Dense(256, activation=None)
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self.dense2 = layers.Dense(128, activation=None)
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self.ln1 = layers.LayerNormalization()
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self.ln2 = layers.LayerNormalization()
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def call(self, x, ln=False):
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assert x.get_shape().as_list()[-1] == 512 and len(x.get_shape().as_list()) == 3
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x = flatten_two_dims(x) # shape=(None,512)
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x = self.dense1(x) # shape=(None,256)
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x = self.ln1(x) # layer norm
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x = tf.nn.relu(x) # relu
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x = self.dense2(x) # shape=(None,128)
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x = self.ln2(x)
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return x
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class ContrastiveHead(tf.keras.Model):
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def __init__(self, temperature, z_dim=128, name=None):
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super(ContrastiveHead, self).__init__(name=name)
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self.W = tf.Variable(tf.random.uniform((z_dim, z_dim)), name='W_Contras')
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self.temperature = temperature
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def call(self, z_a_pos):
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z_a, z_pos = z_a_pos
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Wz = tf.linalg.matmul(self.W, z_pos, transpose_b=True) # (z_dim,B) Wz.shape = (50,32)
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logits = tf.linalg.matmul(z_a, Wz) # (B,B) logits.shape = (32,32)
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logits = logits - tf.reduce_max(logits, 1)[:, None] # logits
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logits = logits * self.temperature
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return logits
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def rec_log_prob(rec_params, s_next, min_sigma=1e-2):
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# rec_params.shape = (None, None, 1024)
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distr = normal_parse_params(rec_params, min_sigma)
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log_prob = distr.log_prob(s_next) # (None, None, 512)
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assert len(log_prob.get_shape().as_list()) == 3 and log_prob.get_shape().as_list()[-1] == 512
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return tf.reduce_sum(log_prob, axis=-1)
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def normal_parse_params(params, min_sigma=0.0):
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n = params.shape[0]
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d = params.shape[-1] # channel
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mu = params[..., :d // 2] #
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sigma_params = params[..., d // 2:]
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sigma = tf.math.softplus(sigma_params)
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sigma = tf.clip_by_value(t=sigma, clip_value_min=min_sigma, clip_value_max=1e5)
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distr = tfd.Normal(loc=mu, scale=sigma) #
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return distr
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def tile_images(array, n_cols=None, max_images=None, div=1):
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if max_images is not None:
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array = array[:max_images]
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if len(array.shape) == 4 and array.shape[3] == 1:
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array = array[:, :, :, 0]
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assert len(array.shape) in [3, 4], "wrong number of dimensions - shape {}".format(array.shape)
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if len(array.shape) == 4:
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assert array.shape[3] == 3, "wrong number of channels- shape {}".format(array.shape)
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if n_cols is None:
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n_cols = max(int(np.sqrt(array.shape[0])) // div * div, div)
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n_rows = int(np.ceil(float(array.shape[0]) / n_cols))
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def cell(i, j):
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ind = i * n_cols + j
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return array[ind] if ind < array.shape[0] else np.zeros(array[0].shape)
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def row(i):
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return np.concatenate([cell(i, j) for j in range(n_cols)], axis=1)
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return np.concatenate([row(i) for i in range(n_rows)], axis=0)
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import distutils.spawn
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import subprocess
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def save_np_as_mp4(frames, filename, frames_per_sec=30):
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print(filename)
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if distutils.spawn.find_executable('avconv') is not None:
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backend = 'avconv'
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elif distutils.spawn.find_executable('ffmpeg') is not None:
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backend = 'ffmpeg'
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else:
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raise NotImplementedError(
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"""Found neither the ffmpeg nor avconv executables. On OS X, you can install ffmpeg via `brew install ffmpeg`. On most Ubuntu variants, `sudo apt-get install ffmpeg` should do it. On Ubuntu 14.04, however, you'll need to install avconv with `sudo apt-get install libav-tools`.""")
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h, w = frames[0].shape[:2]
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output_path = filename
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cmdline = (backend,
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'-nostats',
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'-loglevel', 'error', # suppress warnings
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'-y',
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'-r', '%d' % frames_per_sec,
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# input
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'-f', 'rawvideo',
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'-s:v', '{}x{}'.format(w, h),
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'-pix_fmt', 'rgb24',
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'-i', '-', # this used to be /dev/stdin, which is not Windows-friendly
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# output
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'-vcodec', 'libx264',
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'-pix_fmt', 'yuv420p',
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output_path)
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print('saving ', output_path)
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if hasattr(os, 'setsid'): # setsid not present on Windows
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process = subprocess.Popen(cmdline, stdin=subprocess.PIPE, preexec_fn=os.setsid)
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else:
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process = subprocess.Popen(cmdline, stdin=subprocess.PIPE)
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process.stdin.write(np.array(frames).tobytes())
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process.stdin.close()
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ret = process.wait()
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if ret != 0:
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print("VideoRecorder encoder exited with status {}".format(ret))
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# ExponentialSchedule
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class ExponentialSchedule(object):
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def __init__(self, start_value, decay_factor, end_value, outside_value=None):
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"""Exponential Schedule.
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y = start_value * (1.0 - decay_factor) ^ t
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"""
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assert 0.0 <= decay_factor <= 1.0
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self.start_value = start_value
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self.decay_factor = decay_factor
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self.end_value = end_value
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def value(self, t):
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v = self.start_value * np.power(1.0 - self.decay_factor, t/int(1e5))
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return np.maximum(v, self.end_value)
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