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train_ssd.py
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# Copyright 2018 Changan Wang
# 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.
# =============================================================================
from __future__ import absolute_import
from __future__ import division
from __future__ import print_function
import os
import sys
import tensorflow as tf
from net import ssd_net
from dataset import dataset_common
from preprocessing import ssd_preprocessing
from utility import anchor_manipulator
from utility import scaffolds
# hardware related configuration
tf.app.flags.DEFINE_integer(
'num_readers', 8,
'The number of parallel readers that read data from the dataset.')
tf.app.flags.DEFINE_integer(
'num_preprocessing_threads', 24,
'The number of threads used to create the batches.')
tf.app.flags.DEFINE_integer(
'num_cpu_threads', 0,
'The number of cpu cores used to train.')
tf.app.flags.DEFINE_float(
'gpu_memory_fraction', 1., 'GPU memory fraction to use.')
# scaffold related configuration
tf.app.flags.DEFINE_string(
'data_dir', './dataset/tfrecords',
'The directory where the dataset input data is stored.')
tf.app.flags.DEFINE_integer(
'num_classes', 21, 'Number of classes to use in the dataset.')
tf.app.flags.DEFINE_string(
'model_dir', './logs/',
'The directory where the model will be stored.')
tf.app.flags.DEFINE_integer(
'log_every_n_steps', 10,
'The frequency with which logs are printed.')
tf.app.flags.DEFINE_integer(
'save_summary_steps', 500,
'The frequency with which summaries are saved, in seconds.')
tf.app.flags.DEFINE_integer(
'save_checkpoints_secs', 7200,
'The frequency with which the model is saved, in seconds.')
# model related configuration
tf.app.flags.DEFINE_integer(
'train_image_size', 300,
'The size of the input image for the model to use.')
tf.app.flags.DEFINE_integer(
'train_epochs', None,
'The number of epochs to use for training.')
tf.app.flags.DEFINE_integer(
'max_number_of_steps', 120000,
'The max number of steps to use for training.')
tf.app.flags.DEFINE_integer(
'batch_size', 32,
'Batch size for training and evaluation.')
tf.app.flags.DEFINE_string(
'data_format', 'channels_first', # 'channels_first' or 'channels_last'
'A flag to override the data format used in the model. channels_first '
'provides a performance boost on GPU but is not always compatible '
'with CPU. If left unspecified, the data format will be chosen '
'automatically based on whether TensorFlow was built for CPU or GPU.')
tf.app.flags.DEFINE_float(
'negative_ratio', 3., 'Negative ratio in the loss function.')
tf.app.flags.DEFINE_float(
'match_threshold', 0.5, 'Matching threshold in the loss function.')
tf.app.flags.DEFINE_float(
'neg_threshold', 0.5, 'Matching threshold for the negtive examples in the loss function.')
# optimizer related configuration
tf.app.flags.DEFINE_integer(
'tf_random_seed', 20180503, 'Random seed for TensorFlow initializers.')
tf.app.flags.DEFINE_float(
'weight_decay', 5e-4, 'The weight decay on the model weights.')
tf.app.flags.DEFINE_float(
'momentum', 0.9,
'The momentum for the MomentumOptimizer and RMSPropOptimizer.')
tf.app.flags.DEFINE_float('learning_rate', 1e-3, 'Initial learning rate.')
tf.app.flags.DEFINE_float(
'end_learning_rate', 0.000001,
'The minimal end learning rate used by a polynomial decay learning rate.')
# for learning rate piecewise_constant decay
tf.app.flags.DEFINE_string(
'decay_boundaries', '500, 80000, 100000',
'Learning rate decay boundaries by global_step (comma-separated list).')
tf.app.flags.DEFINE_string(
'lr_decay_factors', '0.1, 1, 0.1, 0.01',
'The values of learning_rate decay factor for each segment between boundaries (comma-separated list).')
# checkpoint related configuration
tf.app.flags.DEFINE_string(
'checkpoint_path', './model',
'The path to a checkpoint from which to fine-tune.')
tf.app.flags.DEFINE_string(
'checkpoint_model_scope', 'vgg_16',
'Model scope in the checkpoint. None if the same as the trained model.')
tf.app.flags.DEFINE_string(
'model_scope', 'ssd300',
'Model scope name used to replace the name_scope in checkpoint.')
tf.app.flags.DEFINE_string(
'checkpoint_exclude_scopes', 'ssd300/multibox_head, ssd300/additional_layers, ssd300/conv4_3_scale',
'Comma-separated list of scopes of variables to exclude when restoring from a checkpoint.')
tf.app.flags.DEFINE_boolean(
'ignore_missing_vars', True,
'When restoring a checkpoint would ignore missing variables.')
tf.app.flags.DEFINE_boolean(
'multi_gpu', True,
'Whether there is GPU to use for training.')
FLAGS = tf.app.flags.FLAGS
#CUDA_VISIBLE_DEVICES
def validate_batch_size_for_multi_gpu(batch_size):
"""For multi-gpu, batch-size must be a multiple of the number of
available GPUs.
Note that this should eventually be handled by replicate_model_fn
directly. Multi-GPU support is currently experimental, however,
so doing the work here until that feature is in place.
"""
if FLAGS.multi_gpu:
from tensorflow.python.client import device_lib
local_device_protos = device_lib.list_local_devices()
num_gpus = sum([1 for d in local_device_protos if d.device_type == 'GPU'])
if not num_gpus:
raise ValueError('Multi-GPU mode was specified, but no GPUs '
'were found. To use CPU, run --multi_gpu=False.')
remainder = batch_size % num_gpus
if remainder:
err = ('When running with multiple GPUs, batch size '
'must be a multiple of the number of available GPUs. '
'Found {} GPUs with a batch size of {}; try --batch_size={} instead.'
).format(num_gpus, batch_size, batch_size - remainder)
raise ValueError(err)
return num_gpus
return 0
def get_init_fn():
return scaffolds.get_init_fn_for_scaffold(FLAGS.model_dir, FLAGS.checkpoint_path,
FLAGS.model_scope, FLAGS.checkpoint_model_scope,
FLAGS.checkpoint_exclude_scopes, FLAGS.ignore_missing_vars,
name_remap={'/kernel': '/weights', '/bias': '/biases'})
# couldn't find better way to pass params from input_fn to model_fn
# some tensors used by model_fn must be created in input_fn to ensure they are in the same graph
# but when we put these tensors to labels's dict, the replicate_model_fn will split them into each GPU
# the problem is that they shouldn't be splited
global_anchor_info = dict()
def input_pipeline(dataset_pattern='train-*', is_training=True, batch_size=FLAGS.batch_size):
def input_fn():
out_shape = [FLAGS.train_image_size] * 2
anchor_creator = anchor_manipulator.AnchorCreator(out_shape,
layers_shapes = [(38, 38), (19, 19), (10, 10), (5, 5), (3, 3), (1, 1)],
anchor_scales = [(0.1,), (0.2,), (0.375,), (0.55,), (0.725,), (0.9,)],
extra_anchor_scales = [(0.1414,), (0.2739,), (0.4541,), (0.6315,), (0.8078,), (0.9836,)],
anchor_ratios = [(1., 2., .5), (1., 2., 3., .5, 0.3333), (1., 2., 3., .5, 0.3333), (1., 2., 3., .5, 0.3333), (1., 2., .5), (1., 2., .5)],
layer_steps = [8, 16, 32, 64, 100, 300])
all_anchors, all_num_anchors_depth, all_num_anchors_spatial = anchor_creator.get_all_anchors()
num_anchors_per_layer = []
for ind in range(len(all_anchors)):
num_anchors_per_layer.append(all_num_anchors_depth[ind] * all_num_anchors_spatial[ind])
anchor_encoder_decoder = anchor_manipulator.AnchorEncoder(allowed_borders = [1.0] * 6,
positive_threshold = FLAGS.match_threshold,
ignore_threshold = FLAGS.neg_threshold,
prior_scaling=[0.1, 0.1, 0.2, 0.2])
image_preprocessing_fn = lambda image_, labels_, bboxes_ : ssd_preprocessing.preprocess_image(image_, labels_, bboxes_, out_shape, is_training=is_training, data_format=FLAGS.data_format, output_rgb=False)
anchor_encoder_fn = lambda glabels_, gbboxes_: anchor_encoder_decoder.encode_all_anchors(glabels_, gbboxes_, all_anchors, all_num_anchors_depth, all_num_anchors_spatial)
image, _, shape, loc_targets, cls_targets, match_scores = dataset_common.slim_get_batch(FLAGS.num_classes,
batch_size,
('train' if is_training else 'val'),
os.path.join(FLAGS.data_dir, dataset_pattern),
FLAGS.num_readers,
FLAGS.num_preprocessing_threads,
image_preprocessing_fn,
anchor_encoder_fn,
num_epochs=FLAGS.train_epochs,
is_training=is_training)
global global_anchor_info
global_anchor_info = {'decode_fn': lambda pred : anchor_encoder_decoder.decode_all_anchors(pred, num_anchors_per_layer),
'num_anchors_per_layer': num_anchors_per_layer,
'all_num_anchors_depth': all_num_anchors_depth }
return image, {'shape': shape, 'loc_targets': loc_targets, 'cls_targets': cls_targets, 'match_scores': match_scores}
return input_fn
def modified_smooth_l1(bbox_pred, bbox_targets, bbox_inside_weights=1., bbox_outside_weights=1., sigma=1.):
"""
ResultLoss = outside_weights * SmoothL1(inside_weights * (bbox_pred - bbox_targets))
SmoothL1(x) = 0.5 * (sigma * x)^2, if |x| < 1 / sigma^2
|x| - 0.5 / sigma^2, otherwise
"""
with tf.name_scope('smooth_l1', [bbox_pred, bbox_targets]):
sigma2 = sigma * sigma
inside_mul = tf.multiply(bbox_inside_weights, tf.subtract(bbox_pred, bbox_targets))
smooth_l1_sign = tf.cast(tf.less(tf.abs(inside_mul), 1.0 / sigma2), tf.float32)
smooth_l1_option1 = tf.multiply(tf.multiply(inside_mul, inside_mul), 0.5 * sigma2)
smooth_l1_option2 = tf.subtract(tf.abs(inside_mul), 0.5 / sigma2)
smooth_l1_result = tf.add(tf.multiply(smooth_l1_option1, smooth_l1_sign),
tf.multiply(smooth_l1_option2, tf.abs(tf.subtract(smooth_l1_sign, 1.0))))
outside_mul = tf.multiply(bbox_outside_weights, smooth_l1_result)
return outside_mul
# from scipy.misc import imread, imsave, imshow, imresize
# import numpy as np
# from utility import draw_toolbox
# def save_image_with_bbox(image, labels_, scores_, bboxes_):
# if not hasattr(save_image_with_bbox, "counter"):
# save_image_with_bbox.counter = 0 # it doesn't exist yet, so initialize it
# save_image_with_bbox.counter += 1
# img_to_draw = np.copy(image)
# img_to_draw = draw_toolbox.bboxes_draw_on_img(img_to_draw, labels_, scores_, bboxes_, thickness=2)
# imsave(os.path.join('./debug/{}.jpg').format(save_image_with_bbox.counter), img_to_draw)
# return save_image_with_bbox.counter
def ssd_model_fn(features, labels, mode, params):
"""model_fn for SSD to be used with our Estimator."""
shape = labels['shape']
loc_targets = labels['loc_targets']
cls_targets = labels['cls_targets']
match_scores = labels['match_scores']
global global_anchor_info
decode_fn = global_anchor_info['decode_fn']
num_anchors_per_layer = global_anchor_info['num_anchors_per_layer']
all_num_anchors_depth = global_anchor_info['all_num_anchors_depth']
# bboxes_pred = decode_fn(loc_targets[0])
# bboxes_pred = [tf.reshape(preds, [-1, 4]) for preds in bboxes_pred]
# bboxes_pred = tf.concat(bboxes_pred, axis=0)
# save_image_op = tf.py_func(save_image_with_bbox,
# [ssd_preprocessing.unwhiten_image(features[0]),
# tf.clip_by_value(cls_targets[0], 0, tf.int64.max),
# match_scores[0],
# bboxes_pred],
# tf.int64, stateful=True)
# with tf.control_dependencies([save_image_op]):
#print(all_num_anchors_depth)
with tf.variable_scope(params['model_scope'], default_name=None, values=[features], reuse=tf.AUTO_REUSE):
backbone = ssd_net.VGG16Backbone(params['data_format'])
feature_layers = backbone.forward(features, training=(mode == tf.estimator.ModeKeys.TRAIN))
#print(feature_layers)
location_pred, cls_pred = ssd_net.multibox_head(feature_layers, params['num_classes'], all_num_anchors_depth, data_format=params['data_format'])
if params['data_format'] == 'channels_first':
cls_pred = [tf.transpose(pred, [0, 2, 3, 1]) for pred in cls_pred]
location_pred = [tf.transpose(pred, [0, 2, 3, 1]) for pred in location_pred]
cls_pred = [tf.reshape(pred, [tf.shape(features)[0], -1, params['num_classes']]) for pred in cls_pred]
location_pred = [tf.reshape(pred, [tf.shape(features)[0], -1, 4]) for pred in location_pred]
cls_pred = tf.concat(cls_pred, axis=1)
location_pred = tf.concat(location_pred, axis=1)
cls_pred = tf.reshape(cls_pred, [-1, params['num_classes']])
location_pred = tf.reshape(location_pred, [-1, 4])
with tf.device('/cpu:0'):
with tf.control_dependencies([cls_pred, location_pred]):
with tf.name_scope('post_forward'):
#bboxes_pred = decode_fn(location_pred)
bboxes_pred = tf.map_fn(lambda _preds : decode_fn(_preds),
tf.reshape(location_pred, [tf.shape(features)[0], -1, 4]),
dtype=[tf.float32] * len(num_anchors_per_layer), back_prop=False)
#cls_targets = tf.Print(cls_targets, [tf.shape(bboxes_pred[0]),tf.shape(bboxes_pred[1]),tf.shape(bboxes_pred[2]),tf.shape(bboxes_pred[3])])
bboxes_pred = [tf.reshape(preds, [-1, 4]) for preds in bboxes_pred]
bboxes_pred = tf.concat(bboxes_pred, axis=0)
flaten_cls_targets = tf.reshape(cls_targets, [-1])
flaten_match_scores = tf.reshape(match_scores, [-1])
flaten_loc_targets = tf.reshape(loc_targets, [-1, 4])
# each positive examples has one label
positive_mask = flaten_cls_targets > 0
n_positives = tf.count_nonzero(positive_mask)
batch_n_positives = tf.count_nonzero(cls_targets, -1)
batch_negtive_mask = tf.equal(cls_targets, 0)#tf.logical_and(tf.equal(cls_targets, 0), match_scores > 0.)
batch_n_negtives = tf.count_nonzero(batch_negtive_mask, -1)
batch_n_neg_select = tf.cast(params['negative_ratio'] * tf.cast(batch_n_positives, tf.float32), tf.int32)
batch_n_neg_select = tf.minimum(batch_n_neg_select, tf.cast(batch_n_negtives, tf.int32))
# hard negative mining for classification
predictions_for_bg = tf.nn.softmax(tf.reshape(cls_pred, [tf.shape(features)[0], -1, params['num_classes']]))[:, :, 0]
prob_for_negtives = tf.where(batch_negtive_mask,
0. - predictions_for_bg,
# ignore all the positives
0. - tf.ones_like(predictions_for_bg))
topk_prob_for_bg, _ = tf.nn.top_k(prob_for_negtives, k=tf.shape(prob_for_negtives)[1])
score_at_k = tf.gather_nd(topk_prob_for_bg, tf.stack([tf.range(tf.shape(features)[0]), batch_n_neg_select - 1], axis=-1))
selected_neg_mask = prob_for_negtives >= tf.expand_dims(score_at_k, axis=-1)
# include both selected negtive and all positive examples
final_mask = tf.stop_gradient(tf.logical_or(tf.reshape(tf.logical_and(batch_negtive_mask, selected_neg_mask), [-1]), positive_mask))
total_examples = tf.count_nonzero(final_mask)
cls_pred = tf.boolean_mask(cls_pred, final_mask)
location_pred = tf.boolean_mask(location_pred, tf.stop_gradient(positive_mask))
flaten_cls_targets = tf.boolean_mask(tf.clip_by_value(flaten_cls_targets, 0, params['num_classes']), final_mask)
flaten_loc_targets = tf.stop_gradient(tf.boolean_mask(flaten_loc_targets, positive_mask))
predictions = {
'classes': tf.argmax(cls_pred, axis=-1),
'probabilities': tf.reduce_max(tf.nn.softmax(cls_pred, name='softmax_tensor'), axis=-1),
'loc_predict': bboxes_pred }
cls_accuracy = tf.metrics.accuracy(flaten_cls_targets, predictions['classes'])
metrics = {'cls_accuracy': cls_accuracy}
# Create a tensor named train_accuracy for logging purposes.
tf.identity(cls_accuracy[1], name='cls_accuracy')
tf.summary.scalar('cls_accuracy', cls_accuracy[1])
if mode == tf.estimator.ModeKeys.PREDICT:
return tf.estimator.EstimatorSpec(mode=mode, predictions=predictions)
# Calculate loss, which includes softmax cross entropy and L2 regularization.
#cross_entropy = tf.cond(n_positives > 0, lambda: tf.losses.sparse_softmax_cross_entropy(labels=flaten_cls_targets, logits=cls_pred), lambda: 0.)# * (params['negative_ratio'] + 1.)
#flaten_cls_targets=tf.Print(flaten_cls_targets, [flaten_loc_targets],summarize=50000)
cross_entropy = tf.losses.sparse_softmax_cross_entropy(labels=flaten_cls_targets, logits=cls_pred) * (params['negative_ratio'] + 1.)
# Create a tensor named cross_entropy for logging purposes.
tf.identity(cross_entropy, name='cross_entropy_loss')
tf.summary.scalar('cross_entropy_loss', cross_entropy)
#loc_loss = tf.cond(n_positives > 0, lambda: modified_smooth_l1(location_pred, tf.stop_gradient(flaten_loc_targets), sigma=1.), lambda: tf.zeros_like(location_pred))
loc_loss = modified_smooth_l1(location_pred, flaten_loc_targets, sigma=1.)
#loc_loss = modified_smooth_l1(location_pred, tf.stop_gradient(gtargets))
loc_loss = tf.reduce_mean(tf.reduce_sum(loc_loss, axis=-1), name='location_loss')
tf.summary.scalar('location_loss', loc_loss)
tf.losses.add_loss(loc_loss)
l2_loss_vars = []
for trainable_var in tf.trainable_variables():
if '_bn' not in trainable_var.name:
if 'conv4_3_scale' not in trainable_var.name:
l2_loss_vars.append(tf.nn.l2_loss(trainable_var))
else:
l2_loss_vars.append(tf.nn.l2_loss(trainable_var) * 0.1)
# Add weight decay to the loss. We exclude the batch norm variables because
# doing so leads to a small improvement in accuracy.
total_loss = tf.add(cross_entropy + loc_loss, tf.multiply(params['weight_decay'], tf.add_n(l2_loss_vars), name='l2_loss'), name='total_loss')
if mode == tf.estimator.ModeKeys.TRAIN:
global_step = tf.train.get_or_create_global_step()
lr_values = [params['learning_rate'] * decay for decay in params['lr_decay_factors']]
learning_rate = tf.train.piecewise_constant(tf.cast(global_step, tf.int32),
[int(_) for _ in params['decay_boundaries']],
lr_values)
truncated_learning_rate = tf.maximum(learning_rate, tf.constant(params['end_learning_rate'], dtype=learning_rate.dtype), name='learning_rate')
# Create a tensor named learning_rate for logging purposes.
tf.summary.scalar('learning_rate', truncated_learning_rate)
optimizer = tf.train.MomentumOptimizer(learning_rate=truncated_learning_rate,
momentum=params['momentum'])
optimizer = tf.contrib.estimator.TowerOptimizer(optimizer)
# Batch norm requires update_ops to be added as a train_op dependency.
update_ops = tf.get_collection(tf.GraphKeys.UPDATE_OPS)
with tf.control_dependencies(update_ops):
train_op = optimizer.minimize(total_loss, global_step)
else:
train_op = None
return tf.estimator.EstimatorSpec(
mode=mode,
predictions=predictions,
loss=total_loss,
train_op=train_op,
eval_metric_ops=metrics,
scaffold=tf.train.Scaffold(init_fn=get_init_fn()))
def parse_comma_list(args):
return [float(s.strip()) for s in args.split(',')]
def main(_):
# Using the Winograd non-fused algorithms provides a small performance boost.
os.environ['TF_ENABLE_WINOGRAD_NONFUSED'] = '1'
gpu_options = tf.GPUOptions(per_process_gpu_memory_fraction=FLAGS.gpu_memory_fraction)
config = tf.ConfigProto(allow_soft_placement=True, log_device_placement=False, intra_op_parallelism_threads=FLAGS.num_cpu_threads, inter_op_parallelism_threads=FLAGS.num_cpu_threads, gpu_options=gpu_options)
num_gpus = validate_batch_size_for_multi_gpu(FLAGS.batch_size)
# Set up a RunConfig to only save checkpoints once per training cycle.
run_config = tf.estimator.RunConfig().replace(
save_checkpoints_secs=FLAGS.save_checkpoints_secs).replace(
save_checkpoints_steps=None).replace(
save_summary_steps=FLAGS.save_summary_steps).replace(
keep_checkpoint_max=5).replace(
tf_random_seed=FLAGS.tf_random_seed).replace(
log_step_count_steps=FLAGS.log_every_n_steps).replace(
session_config=config)
replicate_ssd_model_fn = tf.contrib.estimator.replicate_model_fn(ssd_model_fn, loss_reduction=tf.losses.Reduction.MEAN)
ssd_detector = tf.estimator.Estimator(
model_fn=replicate_ssd_model_fn, model_dir=FLAGS.model_dir, config=run_config,
params={
'num_gpus': num_gpus,
'data_format': FLAGS.data_format,
'batch_size': FLAGS.batch_size,
'model_scope': FLAGS.model_scope,
'num_classes': FLAGS.num_classes,
'negative_ratio': FLAGS.negative_ratio,
'match_threshold': FLAGS.match_threshold,
'neg_threshold': FLAGS.neg_threshold,
'weight_decay': FLAGS.weight_decay,
'momentum': FLAGS.momentum,
'learning_rate': FLAGS.learning_rate,
'end_learning_rate': FLAGS.end_learning_rate,
'decay_boundaries': parse_comma_list(FLAGS.decay_boundaries),
'lr_decay_factors': parse_comma_list(FLAGS.lr_decay_factors),
})
tensors_to_log = {
'lr': 'learning_rate',
'ce': 'cross_entropy_loss',
'loc': 'location_loss',
'loss': 'total_loss',
'l2': 'l2_loss',
'acc': 'post_forward/cls_accuracy',
}
logging_hook = tf.train.LoggingTensorHook(tensors=tensors_to_log, every_n_iter=FLAGS.log_every_n_steps,
formatter=lambda dicts: (', '.join(['%s=%.6f' % (k, v) for k, v in dicts.items()])))
#hook = tf.train.ProfilerHook(save_steps=50, output_dir='.', show_memory=True)
print('Starting a training cycle.')
ssd_detector.train(input_fn=input_pipeline(dataset_pattern='train-*', is_training=True, batch_size=FLAGS.batch_size),
hooks=[logging_hook], max_steps=FLAGS.max_number_of_steps)
if __name__ == '__main__':
tf.logging.set_verbosity(tf.logging.INFO)
tf.app.run()
# cls_targets = tf.reshape(cls_targets, [-1])
# match_scores = tf.reshape(match_scores, [-1])
# loc_targets = tf.reshape(loc_targets, [-1, 4])
# # each positive examples has one label
# positive_mask = cls_targets > 0
# n_positives = tf.count_nonzero(positive_mask)
# negtive_mask = tf.logical_and(tf.equal(cls_targets, 0), match_scores > 0.)
# n_negtives = tf.count_nonzero(negtive_mask)
# n_neg_to_select = tf.cast(params['negative_ratio'] * tf.cast(n_positives, tf.float32), tf.int32)
# n_neg_to_select = tf.minimum(n_neg_to_select, tf.cast(n_negtives, tf.int32))
# # hard negative mining for classification
# predictions_for_bg = tf.nn.softmax(cls_pred)[:, 0]
# prob_for_negtives = tf.where(negtive_mask,
# 0. - predictions_for_bg,
# # ignore all the positives
# 0. - tf.ones_like(predictions_for_bg))
# topk_prob_for_bg, _ = tf.nn.top_k(prob_for_negtives, k=n_neg_to_select)
# selected_neg_mask = prob_for_negtives > topk_prob_for_bg[-1]
# # include both selected negtive and all positive examples
# final_mask = tf.stop_gradient(tf.logical_or(tf.logical_and(negtive_mask, selected_neg_mask), positive_mask))
# total_examples = tf.count_nonzero(final_mask)
# glabels = tf.boolean_mask(tf.clip_by_value(cls_targets, 0, FLAGS.num_classes), final_mask)
# cls_pred = tf.boolean_mask(cls_pred, final_mask)
# location_pred = tf.boolean_mask(location_pred, tf.stop_gradient(positive_mask))
# loc_targets = tf.boolean_mask(loc_targets, tf.stop_gradient(positive_mask))