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prediction_model.py
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prediction_model.py
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# Copyright 2016 The TensorFlow Authors All Rights Reserved.
#
# Licensed under the Apache License, Version 2.0 (the "License");
# you may not use this file except in compliance with the License.
# You may obtain a copy of the License at
#
# http://www.apache.org/licenses/LICENSE-2.0
#
# Unless required by applicable law or agreed to in writing, software
# distributed under the License is distributed on an "AS IS" BASIS,
# WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
# See the License for the specific language governing permissions and
# limitations under the License.
# ==============================================================================
"""Model architecture for predictive model, including CDNA, DNA, and STP."""
import numpy as np
import tensorflow as tf
import tensorflow.contrib.slim as slim
from tensorflow.contrib.layers.python import layers as tf_layers
from lstm_ops import basic_conv_lstm_cell
# Amount to use when lower bounding tensors
RELU_SHIFT = 1e-12
# kernel size for DNA and CDNA.
DNA_KERN_SIZE = 5
def construct_model(images,
actions=None,
states=None,
iter_num=-1.0,
k=-1,
use_state=True,
num_masks=10,
stp=False,
cdna=True,
dna=False,
context_frames=2):
"""Build convolutional lstm video predictor using STP, CDNA, or DNA.
Args:
images: tensor of ground truth image sequences
actions: tensor of action sequences
states: tensor of ground truth state sequences
iter_num: tensor of the current training iteration (for sched. sampling)
k: constant used for scheduled sampling. -1 to feed in own prediction.
use_state: True to include state and action in prediction
num_masks: the number of different pixel motion predictions (and
the number of masks for each of those predictions)
stp: True to use Spatial Transformer Predictor (STP)
cdna: True to use Convoluational Dynamic Neural Advection (CDNA)
dna: True to use Dynamic Neural Advection (DNA)
context_frames: number of ground truth frames to pass in before
feeding in own predictions
Returns:
gen_images: predicted future image frames
gen_states: predicted future states
Raises:
ValueError: if more than one network option specified or more than 1 mask
specified for DNA model.
"""
if stp + cdna + dna != 1:
raise ValueError('More than one, or no network option specified.')
batch_size, img_height, img_width, color_channels = images[0].get_shape()[0:4]
lstm_func = basic_conv_lstm_cell
# Generated robot states and images.
gen_states, gen_images = [], []
current_state = states[0]
if k == -1:
feedself = True
else:
# Scheduled sampling:
# Calculate number of ground-truth frames to pass in.
num_ground_truth = tf.to_int32(
tf.round(tf.to_float(batch_size) * (k / (k + tf.exp(iter_num / k)))))
feedself = False
# LSTM state sizes and states.
lstm_size = np.int32(np.array([32, 32, 64, 64, 128, 64, 32]))
lstm_state1, lstm_state2, lstm_state3, lstm_state4 = None, None, None, None
lstm_state5, lstm_state6, lstm_state7 = None, None, None
for image, action in zip(images[:-1], actions[:-1]):
# Reuse variables after the first timestep.
reuse = bool(gen_images)
done_warm_start = len(gen_images) > context_frames - 1
with slim.arg_scope(
[lstm_func, slim.layers.conv2d, slim.layers.fully_connected,
tf_layers.layer_norm, slim.layers.conv2d_transpose],
reuse=reuse):
if feedself and done_warm_start:
# Feed in generated image.
prev_image = gen_images[-1]
elif done_warm_start:
# Scheduled sampling
prev_image = scheduled_sample(image, gen_images[-1], batch_size,
num_ground_truth)
else:
# Always feed in ground_truth
prev_image = image
# Predicted state is always fed back in
state_action = tf.concat(axis=1, values=[action, current_state])
enc0 = slim.layers.conv2d(
prev_image,
32, [5, 5],
stride=2,
scope='scale1_conv1',
normalizer_fn=tf_layers.layer_norm,
normalizer_params={'scope': 'layer_norm1'})
hidden1, lstm_state1 = lstm_func(
enc0, lstm_state1, lstm_size[0], scope='state1')
hidden1 = tf_layers.layer_norm(hidden1, scope='layer_norm2')
hidden2, lstm_state2 = lstm_func(
hidden1, lstm_state2, lstm_size[1], scope='state2')
hidden2 = tf_layers.layer_norm(hidden2, scope='layer_norm3')
enc1 = slim.layers.conv2d(
hidden2, hidden2.get_shape()[3], [3, 3], stride=2, scope='conv2')
hidden3, lstm_state3 = lstm_func(
enc1, lstm_state3, lstm_size[2], scope='state3')
hidden3 = tf_layers.layer_norm(hidden3, scope='layer_norm4')
hidden4, lstm_state4 = lstm_func(
hidden3, lstm_state4, lstm_size[3], scope='state4')
hidden4 = tf_layers.layer_norm(hidden4, scope='layer_norm5')
enc2 = slim.layers.conv2d(
hidden4, hidden4.get_shape()[3], [3, 3], stride=2, scope='conv3')
# Pass in state and action.
smear = tf.reshape(
state_action,
[int(batch_size), 1, 1, int(state_action.get_shape()[1])])
smear = tf.tile(
smear, [1, int(enc2.get_shape()[1]), int(enc2.get_shape()[2]), 1])
if use_state:
enc2 = tf.concat(axis=3, values=[enc2, smear])
enc3 = slim.layers.conv2d(
enc2, hidden4.get_shape()[3], [1, 1], stride=1, scope='conv4')
hidden5, lstm_state5 = lstm_func(
enc3, lstm_state5, lstm_size[4], scope='state5') # last 8x8
hidden5 = tf_layers.layer_norm(hidden5, scope='layer_norm6')
enc4 = slim.layers.conv2d_transpose(
hidden5, hidden5.get_shape()[3], 3, stride=2, scope='convt1')
hidden6, lstm_state6 = lstm_func(
enc4, lstm_state6, lstm_size[5], scope='state6') # 16x16
hidden6 = tf_layers.layer_norm(hidden6, scope='layer_norm7')
# Skip connection.
hidden6 = tf.concat(axis=3, values=[hidden6, enc1]) # both 16x16
enc5 = slim.layers.conv2d_transpose(
hidden6, hidden6.get_shape()[3], 3, stride=2, scope='convt2')
hidden7, lstm_state7 = lstm_func(
enc5, lstm_state7, lstm_size[6], scope='state7') # 32x32
hidden7 = tf_layers.layer_norm(hidden7, scope='layer_norm8')
# Skip connection.
hidden7 = tf.concat(axis=3, values=[hidden7, enc0]) # both 32x32
enc6 = slim.layers.conv2d_transpose(
hidden7,
hidden7.get_shape()[3], 3, stride=2, scope='convt3',
normalizer_fn=tf_layers.layer_norm,
normalizer_params={'scope': 'layer_norm9'})
if dna:
# Using largest hidden state for predicting untied conv kernels.
enc7 = slim.layers.conv2d_transpose(
enc6, DNA_KERN_SIZE**2, 1, stride=1, scope='convt4')
else:
# Using largest hidden state for predicting a new image layer.
enc7 = slim.layers.conv2d_transpose(
enc6, color_channels, 1, stride=1, scope='convt4')
# This allows the network to also generate one image from scratch,
# which is useful when regions of the image become unoccluded.
transformed = [tf.nn.sigmoid(enc7)]
if stp:
stp_input0 = tf.reshape(hidden5, [int(batch_size), -1])
stp_input1 = slim.layers.fully_connected(
stp_input0, 100, scope='fc_stp')
transformed += stp_transformation(prev_image, stp_input1, num_masks)
elif cdna:
cdna_input = tf.reshape(hidden5, [int(batch_size), -1])
transformed += cdna_transformation(prev_image, cdna_input, num_masks,
int(color_channels))
elif dna:
# Only one mask is supported (more should be unnecessary).
if num_masks != 1:
raise ValueError('Only one mask is supported for DNA model.')
transformed = [dna_transformation(prev_image, enc7)]
masks = slim.layers.conv2d_transpose(
enc6, num_masks + 1, 1, stride=1, scope='convt7')
masks = tf.reshape(
tf.nn.softmax(tf.reshape(masks, [-1, num_masks + 1])),
[int(batch_size), int(img_height), int(img_width), num_masks + 1])
mask_list = tf.split(axis=3, num_or_size_splits=num_masks + 1, value=masks)
output = mask_list[0] * prev_image
for layer, mask in zip(transformed, mask_list[1:]):
output += layer * mask
gen_images.append(output)
current_state = slim.layers.fully_connected(
state_action,
int(current_state.get_shape()[1]),
scope='state_pred',
activation_fn=None)
gen_states.append(current_state)
return gen_images, gen_states
## Utility functions
def stp_transformation(prev_image, stp_input, num_masks):
"""Apply spatial transformer predictor (STP) to previous image.
Args:
prev_image: previous image to be transformed.
stp_input: hidden layer to be used for computing STN parameters.
num_masks: number of masks and hence the number of STP transformations.
Returns:
List of images transformed by the predicted STP parameters.
"""
# Only import spatial transformer if needed.
from spatial_transformer import transformer
identity_params = tf.convert_to_tensor(
np.array([1.0, 0.0, 0.0, 0.0, 1.0, 0.0], np.float32))
transformed = []
for i in range(num_masks - 1):
params = slim.layers.fully_connected(
stp_input, 6, scope='stp_params' + str(i),
activation_fn=None) + identity_params
transformed.append(transformer(prev_image, params))
return transformed
def cdna_transformation(prev_image, cdna_input, num_masks, color_channels):
"""Apply convolutional dynamic neural advection to previous image.
Args:
prev_image: previous image to be transformed.
cdna_input: hidden lyaer to be used for computing CDNA kernels.
num_masks: the number of masks and hence the number of CDNA transformations.
color_channels: the number of color channels in the images.
Returns:
List of images transformed by the predicted CDNA kernels.
"""
batch_size = int(cdna_input.get_shape()[0])
height = int(prev_image.get_shape()[1])
width = int(prev_image.get_shape()[2])
# Predict kernels using linear function of last hidden layer.
cdna_kerns = slim.layers.fully_connected(
cdna_input,
DNA_KERN_SIZE * DNA_KERN_SIZE * num_masks,
scope='cdna_params',
activation_fn=None)
# Reshape and normalize.
cdna_kerns = tf.reshape(
cdna_kerns, [batch_size, DNA_KERN_SIZE, DNA_KERN_SIZE, 1, num_masks])
cdna_kerns = tf.nn.relu(cdna_kerns - RELU_SHIFT) + RELU_SHIFT
norm_factor = tf.reduce_sum(cdna_kerns, [1, 2, 3], keep_dims=True)
cdna_kerns /= norm_factor
# Treat the color channel dimension as the batch dimension since the same
# transformation is applied to each color channel.
# Treat the batch dimension as the channel dimension so that
# depthwise_conv2d can apply a different transformation to each sample.
cdna_kerns = tf.transpose(cdna_kerns, [1, 2, 0, 4, 3])
cdna_kerns = tf.reshape(cdna_kerns, [DNA_KERN_SIZE, DNA_KERN_SIZE, batch_size, num_masks])
# Swap the batch and channel dimensions.
prev_image = tf.transpose(prev_image, [3, 1, 2, 0])
# Transform image.
transformed = tf.nn.depthwise_conv2d(prev_image, cdna_kerns, [1, 1, 1, 1], 'SAME')
# Transpose the dimensions to where they belong.
transformed = tf.reshape(transformed, [color_channels, height, width, batch_size, num_masks])
transformed = tf.transpose(transformed, [3, 1, 2, 0, 4])
transformed = tf.unstack(transformed, axis=-1)
return transformed
def dna_transformation(prev_image, dna_input):
"""Apply dynamic neural advection to previous image.
Args:
prev_image: previous image to be transformed.
dna_input: hidden lyaer to be used for computing DNA transformation.
Returns:
List of images transformed by the predicted CDNA kernels.
"""
# Construct translated images.
prev_image_pad = tf.pad(prev_image, [[0, 0], [2, 2], [2, 2], [0, 0]])
image_height = int(prev_image.get_shape()[1])
image_width = int(prev_image.get_shape()[2])
inputs = []
for xkern in range(DNA_KERN_SIZE):
for ykern in range(DNA_KERN_SIZE):
inputs.append(
tf.expand_dims(
tf.slice(prev_image_pad, [0, xkern, ykern, 0],
[-1, image_height, image_width, -1]), [3]))
inputs = tf.concat(axis=3, values=inputs)
# Normalize channels to 1.
kernel = tf.nn.relu(dna_input - RELU_SHIFT) + RELU_SHIFT
kernel = tf.expand_dims(
kernel / tf.reduce_sum(
kernel, [3], keep_dims=True), [4])
return tf.reduce_sum(kernel * inputs, [3], keep_dims=False)
def scheduled_sample(ground_truth_x, generated_x, batch_size, num_ground_truth):
"""Sample batch with specified mix of ground truth and generated data points.
Args:
ground_truth_x: tensor of ground-truth data points.
generated_x: tensor of generated data points.
batch_size: batch size
num_ground_truth: number of ground-truth examples to include in batch.
Returns:
New batch with num_ground_truth sampled from ground_truth_x and the rest
from generated_x.
"""
idx = tf.random_shuffle(tf.range(int(batch_size)))
ground_truth_idx = tf.gather(idx, tf.range(num_ground_truth))
generated_idx = tf.gather(idx, tf.range(num_ground_truth, int(batch_size)))
ground_truth_examps = tf.gather(ground_truth_x, ground_truth_idx)
generated_examps = tf.gather(generated_x, generated_idx)
return tf.dynamic_stitch([ground_truth_idx, generated_idx],
[ground_truth_examps, generated_examps])