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eval_ssd_network.py
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eval_ssd_network.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.
# ==============================================================================
"""Generic evaluation script that evaluates a SSD model
on a given dataset."""
import math
import sys
import six
import time
import numpy as np
import tensorflow as tf
import tf_extended as tfe
import tf_utils
from tensorflow.python.framework import ops
from datasets import dataset_factory
from nets import nets_factory
from preprocessing import preprocessing_factory
slim = tf.contrib.slim
# =========================================================================== #
# Some default EVAL parameters
# =========================================================================== #
# List of recalls values at which precision is evaluated.
LIST_RECALLS = [0.1, 0.2, 0.3, 0.4, 0.5, 0.6, 0.7, 0.8, 0.85,
0.90, 0.95, 0.96, 0.97, 0.98, 0.99]
DATA_FORMAT = 'NHWC'
# =========================================================================== #
# SSD evaluation Flags.
# =========================================================================== #
tf.app.flags.DEFINE_float(
'select_threshold', 0.01, 'Selection threshold.')
tf.app.flags.DEFINE_integer(
'select_top_k', 400, 'Select top-k detected bounding boxes.')
tf.app.flags.DEFINE_integer(
'keep_top_k', 200, 'Keep top-k detected objects.')
tf.app.flags.DEFINE_float(
'nms_threshold', 0.45, 'Non-Maximum Selection threshold.')
tf.app.flags.DEFINE_float(
'matching_threshold', 0.5, 'Matching threshold with groundtruth objects.')
tf.app.flags.DEFINE_integer(
'eval_resize', 4, 'Image resizing: None / CENTRAL_CROP / PAD_AND_RESIZE / WARP_RESIZE.')
tf.app.flags.DEFINE_integer(
'eval_image_size', None, 'Eval image size.')
tf.app.flags.DEFINE_boolean(
'remove_difficult', True, 'Remove difficult objects from evaluation.')
# =========================================================================== #
# Main evaluation flags.
# =========================================================================== #
tf.app.flags.DEFINE_integer(
'num_classes', 21, 'Number of classes to use in the dataset.')
tf.app.flags.DEFINE_integer(
'batch_size', 1, 'The number of samples in each batch.')
tf.app.flags.DEFINE_integer(
'max_num_batches', None,
'Max number of batches to evaluate by default use all.')
tf.app.flags.DEFINE_string(
'master', '', 'The address of the TensorFlow master to use.')
tf.app.flags.DEFINE_string(
'checkpoint_path', '/tmp/tfmodel/',
'The directory where the model was written to or an absolute path to a '
'checkpoint file.')
tf.app.flags.DEFINE_string(
'eval_dir', '/tmp/tfmodel/', 'Directory where the results are saved to.')
tf.app.flags.DEFINE_integer(
'num_preprocessing_threads', 4,
'The number of threads used to create the batches.')
tf.app.flags.DEFINE_string(
'dataset_name', 'imagenet', 'The name of the dataset to load.')
tf.app.flags.DEFINE_string(
'dataset_split_name', 'test', 'The name of the train/test split.')
tf.app.flags.DEFINE_string(
'dataset_dir', None, 'The directory where the dataset files are stored.')
tf.app.flags.DEFINE_string(
'model_name', 'inception_v3', 'The name of the architecture to evaluate.')
tf.app.flags.DEFINE_string(
'preprocessing_name', None, 'The name of the preprocessing to use. If left '
'as `None`, then the model_name flag is used.')
tf.app.flags.DEFINE_float(
'moving_average_decay', None,
'The decay to use for the moving average.'
'If left as None, then moving averages are not used.')
tf.app.flags.DEFINE_float(
'gpu_memory_fraction', 0.1, 'GPU memory fraction to use.')
tf.app.flags.DEFINE_boolean(
'wait_for_checkpoints', False, 'Wait for new checkpoints in the eval loop.')
FLAGS = tf.app.flags.FLAGS
def main(_):
if not FLAGS.dataset_dir:
raise ValueError('You must supply the dataset directory with --dataset_dir')
tf.logging.set_verbosity(tf.logging.INFO)
with tf.Graph().as_default():
tf_global_step = slim.get_or_create_global_step()
# =================================================================== #
# Dataset + SSD model + Pre-processing
# =================================================================== #
dataset = dataset_factory.get_dataset(
FLAGS.dataset_name, FLAGS.dataset_split_name, FLAGS.dataset_dir)
# Get the SSD network and its anchors.
ssd_class = nets_factory.get_network(FLAGS.model_name)
ssd_params = ssd_class.default_params._replace(num_classes=FLAGS.num_classes)
ssd_net = ssd_class(ssd_params)
# Evaluation shape and associated anchors: eval_image_size
ssd_shape = ssd_net.params.img_shape
ssd_anchors = ssd_net.anchors(ssd_shape)
# Select the preprocessing function.
preprocessing_name = FLAGS.preprocessing_name or FLAGS.model_name
image_preprocessing_fn = preprocessing_factory.get_preprocessing(
preprocessing_name, is_training=False)
tf_utils.print_configuration(FLAGS.__flags, ssd_params,
dataset.data_sources, FLAGS.eval_dir)
# =================================================================== #
# Create a dataset provider and batches.
# =================================================================== #
with tf.device('/cpu:0'):
with tf.name_scope(FLAGS.dataset_name + '_data_provider'):
provider = slim.dataset_data_provider.DatasetDataProvider(
dataset,
common_queue_capacity=2 * FLAGS.batch_size,
common_queue_min=FLAGS.batch_size,
shuffle=False)
# Get for SSD network: image, labels, bboxes.
[image, shape, glabels, gbboxes] = provider.get(['image', 'shape',
'object/label',
'object/bbox'])
if FLAGS.remove_difficult:
[gdifficults] = provider.get(['object/difficult'])
else:
gdifficults = tf.zeros(tf.shape(glabels), dtype=tf.int64)
# Pre-processing image, labels and bboxes.
image, glabels, gbboxes, gbbox_img = \
image_preprocessing_fn(image, glabels, gbboxes,
out_shape=ssd_shape,
data_format=DATA_FORMAT,
resize=FLAGS.eval_resize,
difficults=None)
# Encode groundtruth labels and bboxes.
gclasses, glocalisations, gscores = \
ssd_net.bboxes_encode(glabels, gbboxes, ssd_anchors)
batch_shape = [1] * 5 + [len(ssd_anchors)] * 3
# Evaluation batch.
r = tf.train.batch(
tf_utils.reshape_list([image, glabels, gbboxes, gdifficults, gbbox_img,
gclasses, glocalisations, gscores]),
batch_size=FLAGS.batch_size,
num_threads=FLAGS.num_preprocessing_threads,
capacity=5 * FLAGS.batch_size,
dynamic_pad=True)
(b_image, b_glabels, b_gbboxes, b_gdifficults, b_gbbox_img, b_gclasses,
b_glocalisations, b_gscores) = tf_utils.reshape_list(r, batch_shape)
# =================================================================== #
# SSD Network + Ouputs decoding.
# =================================================================== #
dict_metrics = {}
arg_scope = ssd_net.arg_scope(data_format=DATA_FORMAT)
with slim.arg_scope(arg_scope):
predictions, localisations, logits, end_points = \
ssd_net.net(b_image, is_training=False)
# Add losses functions.
ssd_net.losses(logits, localisations,
b_gclasses, b_glocalisations, b_gscores)
# Performing post-processing on CPU: loop-intensive, usually more efficient.
with tf.device('/device:CPU:0'):
# Detected objects from SSD output.
localisations = ssd_net.bboxes_decode(localisations, ssd_anchors)
rscores, rbboxes = \
ssd_net.detected_bboxes(predictions, localisations,
select_threshold=FLAGS.select_threshold,
nms_threshold=FLAGS.nms_threshold,
clipping_bbox=None,
top_k=FLAGS.select_top_k,
keep_top_k=FLAGS.keep_top_k)
# Compute TP and FP statistics.
num_gbboxes, tp, fp, rscores = \
tfe.bboxes_matching_batch(rscores.keys(), rscores, rbboxes,
b_glabels, b_gbboxes, b_gdifficults,
matching_threshold=FLAGS.matching_threshold)
# Variables to restore: moving avg. or normal weights.
if FLAGS.moving_average_decay:
variable_averages = tf.train.ExponentialMovingAverage(
FLAGS.moving_average_decay, tf_global_step)
variables_to_restore = variable_averages.variables_to_restore(
slim.get_model_variables())
variables_to_restore[tf_global_step.op.name] = tf_global_step
else:
variables_to_restore = slim.get_variables_to_restore()
# =================================================================== #
# Evaluation metrics.
# =================================================================== #
with tf.device('/device:CPU:0'):
dict_metrics = {}
# First add all losses.
for loss in tf.get_collection(tf.GraphKeys.LOSSES):
dict_metrics[loss.op.name] = slim.metrics.streaming_mean(loss)
# Extra losses as well.
for loss in tf.get_collection('EXTRA_LOSSES'):
dict_metrics[loss.op.name] = slim.metrics.streaming_mean(loss)
# Add metrics to summaries and Print on screen.
for name, metric in dict_metrics.items():
# summary_name = 'eval/%s' % name
summary_name = name
op = tf.summary.scalar(summary_name, metric[0], collections=[])
# op = tf.Print(op, [metric[0]], summary_name)
tf.add_to_collection(tf.GraphKeys.SUMMARIES, op)
# FP and TP metrics.
tp_fp_metric = tfe.streaming_tp_fp_arrays(num_gbboxes, tp, fp, rscores)
for c in tp_fp_metric[0].keys():
dict_metrics['tp_fp_%s' % c] = (tp_fp_metric[0][c],
tp_fp_metric[1][c])
# Add to summaries precision/recall values.
aps_voc07 = {}
aps_voc12 = {}
for c in tp_fp_metric[0].keys():
# Precison and recall values.
prec, rec = tfe.precision_recall(*tp_fp_metric[0][c])
# Average precision VOC07.
v = tfe.average_precision_voc07(prec, rec)
summary_name = 'AP_VOC07/%s' % c
op = tf.summary.scalar(summary_name, v, collections=[])
# op = tf.Print(op, [v], summary_name)
tf.add_to_collection(tf.GraphKeys.SUMMARIES, op)
aps_voc07[c] = v
# Average precision VOC12.
v = tfe.average_precision_voc12(prec, rec)
summary_name = 'AP_VOC12/%s' % c
op = tf.summary.scalar(summary_name, v, collections=[])
# op = tf.Print(op, [v], summary_name)
tf.add_to_collection(tf.GraphKeys.SUMMARIES, op)
aps_voc12[c] = v
# Mean average precision VOC07.
summary_name = 'AP_VOC07/mAP'
mAP = tf.add_n(list(aps_voc07.values())) / len(aps_voc07)
op = tf.summary.scalar(summary_name, mAP, collections=[])
op = tf.Print(op, [mAP], summary_name)
tf.add_to_collection(tf.GraphKeys.SUMMARIES, op)
# Mean average precision VOC12.
summary_name = 'AP_VOC12/mAP'
mAP = tf.add_n(list(aps_voc12.values())) / len(aps_voc12)
op = tf.summary.scalar(summary_name, mAP, collections=[])
op = tf.Print(op, [mAP], summary_name)
tf.add_to_collection(tf.GraphKeys.SUMMARIES, op)
# for i, v in enumerate(l_precisions):
# summary_name = 'eval/precision_at_recall_%.2f' % LIST_RECALLS[i]
# op = tf.summary.scalar(summary_name, v, collections=[])
# op = tf.Print(op, [v], summary_name)
# tf.add_to_collection(tf.GraphKeys.SUMMARIES, op)
# Split into values and updates ops.
names_to_values, names_to_updates = slim.metrics.aggregate_metric_map(dict_metrics)
# =================================================================== #
# Evaluation loop.
# =================================================================== #
gpu_options = tf.GPUOptions(per_process_gpu_memory_fraction=FLAGS.gpu_memory_fraction)
config = tf.ConfigProto(log_device_placement=False, gpu_options=gpu_options)
# config.graph_options.optimizer_options.global_jit_level = tf.OptimizerOptions.ON_1
# Number of batches...
if FLAGS.max_num_batches:
num_batches = FLAGS.max_num_batches
else:
num_batches = math.ceil(dataset.num_samples / float(FLAGS.batch_size))
if not FLAGS.wait_for_checkpoints:
if tf.gfile.IsDirectory(FLAGS.checkpoint_path):
checkpoint_path = tf.train.latest_checkpoint(FLAGS.checkpoint_path)
else:
checkpoint_path = FLAGS.checkpoint_path
tf.logging.info('Evaluating %s' % checkpoint_path)
# Standard evaluation loop.
start = time.time()
slim.evaluation.evaluate_once(
master=FLAGS.master,
checkpoint_path=checkpoint_path,
logdir=FLAGS.eval_dir,
num_evals=num_batches,
eval_op=list(names_to_updates.values()),
variables_to_restore=variables_to_restore,
session_config=config)
# Log time spent.
elapsed = time.time()
elapsed = elapsed - start
print('Time spent : %.3f seconds.' % elapsed)
print('Time spent per BATCH: %.3f seconds.' % (elapsed / num_batches))
else:
checkpoint_path = FLAGS.checkpoint_path
tf.logging.info('Evaluating %s' % checkpoint_path)
# Waiting loop.
slim.evaluation.evaluation_loop(
master=FLAGS.master,
checkpoint_dir=checkpoint_path,
logdir=FLAGS.eval_dir,
num_evals=num_batches,
eval_op=list(names_to_updates.values()),
variables_to_restore=variables_to_restore,
eval_interval_secs=60,
max_number_of_evaluations=np.inf,
session_config=config,
timeout=None)
if __name__ == '__main__':
tf.app.run()