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eval_imagenet.py
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eval_imagenet.py
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# Copyright 2018 Google LLC
#
# 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
#
# https://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.
# ==============================================================================
"""Generic train."""
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import os
from absl import flags
import tensorflow as tf
import generator as generator_module
import utils_ori as utils
slim = tf.contrib.slim
tfgan = tf.contrib.gan
flags.DEFINE_string(
# 'data_dir', '/gpu/hz138/Data/imagenet', #'/home/hz138/Data/imagenet',
'data_dir', '/bigdata1/hz138/Data/imagenet',
'Directory with Imagenet input data as sharded recordio files of pre-'
'processed images.')
flags.DEFINE_integer('z_dim', 128, 'The dimension of z')
flags.DEFINE_integer('gf_dim', 64, 'Dimensionality of gf. [64]')
flags.DEFINE_string('master', 'local',
'BNS name of the TensorFlow master to use')
flags.DEFINE_string('checkpoint_dir', 'checkpoint', 'Directory name to load '
'the checkpoints. [checkpoint]')
flags.DEFINE_string('sample_dir', 'sample', 'Directory name to save the '
'image samples. [sample]')
flags.DEFINE_string('eval_dir', 'checkpoint/eval', 'Directory name to save the '
'eval summaries . [eval]')
flags.DEFINE_integer('batch_size', 64, 'Batch size of samples to feed into '
'Inception models for evaluation. [16]')
flags.DEFINE_integer('shuffle_buffer_size', 5000, 'Number of records to load '
'before shuffling and yielding for consumption. [5000]')
flags.DEFINE_integer('dcgan_generator_batch_size', 100, 'Size of batch to feed '
'into generator -- we may stack multiple of these later.')
flags.DEFINE_integer('eval_sample_size', 50000,
'Number of samples to sample from '
'generator and real data. [1024]')
flags.DEFINE_boolean('is_train', False, 'Use DCGAN only for evaluation.')
flags.DEFINE_integer('task', 0, 'The task id of the current worker. [0]')
flags.DEFINE_integer('ps_tasks', 0, 'The number of ps tasks. [0]')
flags.DEFINE_integer('num_workers', 1, 'The number of worker tasks. [1]')
flags.DEFINE_integer('replicas_to_aggregate', 1, 'The number of replicas '
'to aggregate for synchronous optimization [1]')
flags.DEFINE_integer('num_towers', 1, 'The number of GPUs to use per task. [1]')
flags.DEFINE_integer('eval_interval_secs', 300,
'Frequency of generator evaluation with Inception score '
'and Frechet Inception Distance. [300]')
flags.DEFINE_integer('num_classes', 1000, 'The number of classes in the dataset')
flags.DEFINE_string('generator_type', 'test', 'test or baseline')
FLAGS = flags.FLAGS
def main(_):
model_dir = '%s_%s' % ('imagenet', FLAGS.batch_size)
FLAGS.eval_dir = FLAGS.checkpoint_dir + '/eval'
checkpoint_dir = os.path.join(FLAGS.checkpoint_dir, model_dir)
log_dir = os.path.join(FLAGS.eval_dir, model_dir)
print('log_dir', log_dir)
graph_def = None # pylint: disable=protected-access
# Batch size to feed batches of images through Inception and the generator
# to extract feature vectors to later stack together and compute metrics.
local_batch_size = FLAGS.dcgan_generator_batch_size
if FLAGS.generator_type == 'baseline':
generator_fn = generator_module.generator
elif FLAGS.generator_type == 'test':
generator_fn = generator_module.generator_test
else:
raise NotImplementedError
if FLAGS.num_towers != 1 or FLAGS.num_workers != 1:
raise NotImplementedError(
'The eval job does not currently support using multiple GPUs')
# Get activations from real images.
with tf.device('/device:CPU:1'):
real_pools, real_images = utils.get_real_activations(
FLAGS.data_dir,
local_batch_size,
FLAGS.eval_sample_size // local_batch_size,
label_offset=-1,
shuffle_buffer_size=FLAGS.shuffle_buffer_size)
num_classes = FLAGS.num_classes
gen_class_logits = tf.zeros((local_batch_size, num_classes))
gen_class_ints = tf.multinomial(gen_class_logits, 1)
gen_sparse_class = tf.squeeze(gen_class_ints)
# Generate the first batch of generated images and extract activations;
# this bootstraps the while_loop with a pools and logits tensor.
test_zs = utils.make_z_normal(1, local_batch_size, FLAGS.z_dim)
generator = generator_fn(
test_zs[0],
gen_sparse_class,
FLAGS.gf_dim,
FLAGS.num_classes,
is_training=False)
pools, logits = utils.run_custom_inception(
generator, output_tensor=['pool_3:0', 'logits:0'], graph_def=graph_def)
# Set up while_loop to compute activations of generated images from generator.
def while_cond(g_pools, g_logits, i): # pylint: disable=unused-argument
return tf.less(i, FLAGS.eval_sample_size // local_batch_size)
# We use a while loop because we want to generate a batch of images
# and then feed that batch through Inception to retrieve the activations.
# Otherwise, if we generate all the samples first and then compute all the
# activations, we will run out of memory.
def while_body(g_pools, g_logits, i):
with tf.control_dependencies([g_pools, g_logits]):
test_zs = utils.make_z_normal(1, local_batch_size, FLAGS.z_dim)
# Uniform distribution
gen_class_logits = tf.zeros((local_batch_size, num_classes))
gen_class_ints = tf.multinomial(gen_class_logits, 1)
gen_sparse_class = tf.squeeze(gen_class_ints)
generator = generator_fn(
test_zs[0],
gen_sparse_class,
FLAGS.gf_dim,
FLAGS.num_classes,
is_training=False)
pools, logits = utils.run_custom_inception(
generator,
output_tensor=['pool_3:0', 'logits:0'],
graph_def=graph_def)
g_pools = tf.concat([g_pools, pools], 0)
g_logits = tf.concat([g_logits, logits], 0)
return (g_pools, g_logits, tf.add(i, 1))
# Get the activations
i = tf.constant(1)
new_generator_pools_list, new_generator_logits_list, _ = tf.while_loop(
while_cond,
while_body, [pools, logits, i],
shape_invariants=[
tf.TensorShape([None, 2048]),
tf.TensorShape([None, 1008]),
i.get_shape()
],
parallel_iterations=1,
back_prop=False,
swap_memory=True,
name='GeneratedActivations')
new_generator_pools_list.set_shape([FLAGS.eval_sample_size, 2048])
new_generator_logits_list.set_shape([FLAGS.eval_sample_size, 1008])
# Get a small batch of samples from generator to dispaly in TensorBoard
vis_batch_size = 16
eval_vis_zs = utils.make_z_normal(
1, vis_batch_size, FLAGS.z_dim)
gen_class_logits_vis = tf.zeros((vis_batch_size, num_classes))
gen_class_ints_vis = tf.multinomial(gen_class_logits_vis, 1)
gen_sparse_class_vis = tf.squeeze(gen_class_ints_vis)
eval_vis_images = generator_fn(
eval_vis_zs[0],
gen_sparse_class_vis,
FLAGS.gf_dim,
FLAGS.num_classes,
is_training=False
)
eval_vis_images = tf.cast((eval_vis_images + 1.) * 127.5, tf.uint8)
with tf.variable_scope('eval_vis'):
tf.summary.image('generated_images', eval_vis_images)
tf.summary.image('real_images', real_images)
tf.summary.image('real_images_grid',
tfgan.eval.image_grid(
real_images[:16],
grid_shape=utils.squarest_grid_size(16),
image_shape=(128, 128)))
tf.summary.image('generated_images_grid',
tfgan.eval.image_grid(
eval_vis_images[:16],
grid_shape=utils.squarest_grid_size(16),
image_shape=(128, 128)))
# Use the activations from the real images and generated images to compute
# Inception score and FID.
generated_logits = tf.concat(new_generator_logits_list, 0)
generated_pools = tf.concat(new_generator_pools_list, 0)
# Compute Frechet Inception Distance and Inception score
incscore = tfgan.eval.classifier_score_from_logits(generated_logits)
fid = tfgan.eval.frechet_classifier_distance_from_activations(
real_pools, generated_pools)
with tf.variable_scope('eval'):
tf.summary.scalar('fid', fid)
tf.summary.scalar('incscore', incscore)
session_config = tf.ConfigProto(
allow_soft_placement=True, log_device_placement=False)
tf.contrib.training.evaluate_repeatedly(
checkpoint_dir=checkpoint_dir,
hooks=[
tf.contrib.training.SummaryAtEndHook(log_dir),
tf.contrib.training.StopAfterNEvalsHook(1)
],
config=session_config)
if __name__ == '__main__':
tf.app.run()