https://github.com/google-research/fixmatch
Tip revision: d4985a158065947dba803e626ee9a6721709c570 authored by David Berthelot on 12 November 2020, 17:50:23 UTC
Merge pull request #46 from daikikatsuragawa/master
Merge pull request #46 from daikikatsuragawa/master
Tip revision: d4985a1
uda.py
# Copyright 2019 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.
"""Unsupervised data augmentation (UDA)
"""
import functools
import os
import numpy as np
import tensorflow as tf
from absl import app
from absl import flags
from tqdm import trange
from libml import models, utils
from libml.data import PAIR_DATASETS
FLAGS = flags.FLAGS
class UDA(models.MultiModel):
TSA_MODES = 'no exp linear log'.split()
def tsa_threshold(self, tsa, scale=5, tsa_pos=10, **kwargs):
del kwargs
# step ratio will be maxed at (2 ** 14) * (2 ** 10) ~ 16.8M updates
step_ratio = tf.to_float(self.step) / tf.to_float(min(FLAGS.train_kimg, 1 << 14) << tsa_pos)
if tsa == 'linear':
coeff = step_ratio
elif tsa == 'exp': # [exp(-5), exp(0)] = [1e-2, 1]
coeff = tf.exp((step_ratio - 1) * scale)
elif tsa == 'log': # [1 - exp(0), 1 - exp(-5)] = [0, 0.99]
coeff = 1 - tf.exp((-step_ratio) * scale)
elif tsa == 'no':
coeff = tf.to_float(1.0)
elif tsa != 'no':
raise NotImplementedError(tsa)
coeff = tf.math.minimum(coeff, 1.0) # bound the coefficient
p_min = 1. / self.nclass
return coeff * (1 - p_min) + p_min
def tsa_loss_mask(self, tsa, logits, labels, tsa_pos, **kwargs):
thresh = self.tsa_threshold(tsa, tsa_pos=tsa_pos, **kwargs)
p_class = tf.nn.softmax(logits, axis=-1)
p_correct = tf.reduce_sum(labels * p_class, axis=-1)
loss_mask = tf.cast(p_correct <= thresh, tf.float32) # Ignore confident predictions.
return tf.stop_gradient(loss_mask)
@staticmethod
def confidence_based_masking(logits, p_class=None, thresh=0.9):
if logits is not None:
p_class = tf.nn.softmax(logits, axis=-1)
p_class_max = tf.reduce_max(p_class, axis=-1)
loss_mask = tf.cast(p_class_max >= thresh, tf.float32) # Ignore unconfident predictions.
return tf.stop_gradient(loss_mask)
@staticmethod
def softmax_temperature_controlling(logits, T):
# this is essentially the same as sharpening in mixmatch
logits = logits / T
return tf.stop_gradient(logits)
@staticmethod
def kl_divergence_from_logits(p_logits, q_logits):
p = tf.nn.softmax(p_logits)
log_p = tf.nn.log_softmax(p_logits)
log_q = tf.nn.log_softmax(q_logits)
kl = tf.reduce_sum(p * (log_p - log_q), -1)
return kl
@staticmethod
def entropy_from_logits(logits):
log_prob = tf.nn.log_softmax(logits, axis=-1)
prob = tf.exp(log_prob)
ent = tf.reduce_sum(-prob * log_prob, axis=-1)
return ent
def train(self, train_nimg, report_nimg):
if FLAGS.eval_ckpt:
self.eval_checkpoint(FLAGS.eval_ckpt)
return
batch = FLAGS.batch
train_labeled = self.dataset.train_labeled.repeat().shuffle(FLAGS.shuffle).parse().augment()
train_labeled = train_labeled.batch(batch).prefetch(16).make_one_shot_iterator().get_next()
train_unlabeled = self.dataset.train_unlabeled.repeat().shuffle(FLAGS.shuffle).parse().augment()
train_unlabeled = train_unlabeled.batch(batch * self.params['uratio']).prefetch(16)
train_unlabeled = train_unlabeled.make_one_shot_iterator().get_next()
scaffold = tf.train.Scaffold(saver=tf.train.Saver(max_to_keep=FLAGS.keep_ckpt,
pad_step_number=10))
with tf.Session(config=utils.get_config()) as sess:
self.session = sess
self.cache_eval()
with tf.train.MonitoredTrainingSession(
scaffold=scaffold,
checkpoint_dir=self.checkpoint_dir,
config=utils.get_config(),
save_checkpoint_steps=FLAGS.save_kimg << 10,
save_summaries_steps=report_nimg - batch) as train_session:
self.session = train_session._tf_sess()
gen_labeled = self.gen_labeled_fn(train_labeled)
gen_unlabeled = self.gen_unlabeled_fn(train_unlabeled)
self.tmp.step = self.session.run(self.step)
while self.tmp.step < train_nimg:
loop = trange(self.tmp.step % report_nimg, report_nimg, batch,
leave=False, unit='img', unit_scale=batch,
desc='Epoch %d/%d' % (1 + (self.tmp.step // report_nimg), train_nimg // report_nimg))
for _ in loop:
self.train_step(train_session, gen_labeled, gen_unlabeled)
while self.tmp.print_queue:
loop.write(self.tmp.print_queue.pop(0))
while self.tmp.print_queue:
print(self.tmp.print_queue.pop(0))
def model(self, batch, lr, wd, wu, we, confidence, uratio,
temperature=1.0, tsa='no', tsa_pos=10, ema=0.999, **kwargs):
hwc = [self.dataset.height, self.dataset.width, self.dataset.colors]
xt_in = tf.placeholder(tf.float32, [batch] + hwc, 'xt') # For training
x_in = tf.placeholder(tf.float32, [None] + hwc, 'x')
y_in = tf.placeholder(tf.float32, [batch * uratio, 2] + hwc, 'y')
l_in = tf.placeholder(tf.int32, [batch], 'labels')
l = tf.one_hot(l_in, self.nclass)
lrate = tf.clip_by_value(tf.to_float(self.step) / (FLAGS.train_kimg << 10), 0, 1)
lr *= tf.cos(lrate * (7 * np.pi) / (2 * 8))
tf.summary.scalar('monitors/lr', lr)
# Compute logits for xt_in and y_in
classifier = lambda x, **kw: self.classifier(x, **kw, **kwargs).logits
skip_ops = tf.get_collection(tf.GraphKeys.UPDATE_OPS)
x = utils.interleave(tf.concat([xt_in, y_in[:, 0], y_in[:, 1]], 0), 2 * uratio + 1)
logits = utils.para_cat(lambda x: classifier(x, training=True), x)
logits = utils.de_interleave(logits, 2 * uratio+1)
post_ops = [v for v in tf.get_collection(tf.GraphKeys.UPDATE_OPS) if v not in skip_ops]
logits_x = logits[:batch]
logits_weak, logits_strong = tf.split(logits[batch:], 2)
del logits, skip_ops
# softmax temperature control
logits_weak_tgt = self.softmax_temperature_controlling(logits_weak, T=temperature)
# generate confidence mask based on sharpened distribution
pseudo_labels = tf.stop_gradient(tf.nn.softmax(logits_weak))
pseudo_mask = self.confidence_based_masking(logits=None, p_class=pseudo_labels, thresh=confidence)
tf.summary.scalar('monitors/mask', tf.reduce_mean(pseudo_mask))
tf.summary.scalar('monitors/conf_weak', tf.reduce_mean(tf.reduce_max(tf.nn.softmax(logits_weak), axis=1)))
tf.summary.scalar('monitors/conf_strong', tf.reduce_mean(tf.reduce_max(tf.nn.softmax(logits_strong), axis=1)))
kld = self.kl_divergence_from_logits(logits_weak_tgt, logits_strong)
entropy = self.entropy_from_logits(logits_weak)
loss_xeu = tf.reduce_mean(kld * pseudo_mask)
tf.summary.scalar('losses/xeu', loss_xeu)
loss_ent = tf.reduce_mean(entropy)
tf.summary.scalar('losses/entropy', loss_ent)
# supervised loss with TSA
loss_mask = self.tsa_loss_mask(tsa=tsa, logits=logits_x, labels=l, tsa_pos=tsa_pos)
loss_xe = tf.nn.softmax_cross_entropy_with_logits_v2(labels=l, logits=logits_x)
loss_xe = tf.reduce_sum(loss_xe * loss_mask) / tf.math.maximum(tf.reduce_sum(loss_mask), 1.0)
tf.summary.scalar('losses/xe', loss_xe)
tf.summary.scalar('losses/mask_sup', tf.reduce_mean(loss_mask))
# L2 regularization
loss_wd = sum(tf.nn.l2_loss(v) for v in utils.model_vars('classify') if 'kernel' in v.name)
tf.summary.scalar('losses/wd', loss_wd)
ema = tf.train.ExponentialMovingAverage(decay=ema)
ema_op = ema.apply(utils.model_vars())
ema_getter = functools.partial(utils.getter_ema, ema)
post_ops.append(ema_op)
train_op = tf.train.MomentumOptimizer(lr, 0.9, use_nesterov=True).minimize(
loss_xe + loss_xeu * wu + loss_ent * we + loss_wd * wd, colocate_gradients_with_ops=True)
with tf.control_dependencies([train_op]):
train_op = tf.group(*post_ops)
return utils.EasyDict(
xt=xt_in, x=x_in, y=y_in, label=l_in, train_op=train_op,
classify_raw=tf.nn.softmax(classifier(x_in, training=False)), # No EMA, for debugging.
classify_op=tf.nn.softmax(classifier(x_in, getter=ema_getter, training=False)))
def main(argv):
utils.setup_main()
del argv # Unused.
dataset = PAIR_DATASETS()[FLAGS.dataset]()
log_width = utils.ilog2(dataset.width)
model = UDA(
os.path.join(FLAGS.train_dir, dataset.name),
dataset,
lr=FLAGS.lr,
wd=FLAGS.wd,
wu=FLAGS.wu,
we=FLAGS.we,
arch=FLAGS.arch,
batch=FLAGS.batch,
nclass=dataset.nclass,
temperature=FLAGS.temperature,
tsa=FLAGS.tsa,
tsa_pos=FLAGS.tsa_pos,
confidence=FLAGS.confidence,
uratio=FLAGS.uratio,
scales=FLAGS.scales or (log_width - 2),
filters=FLAGS.filters,
repeat=FLAGS.repeat)
model.train(FLAGS.train_kimg << 10, FLAGS.report_kimg << 10) # 1024 epochs
if __name__ == '__main__':
utils.setup_tf()
flags.DEFINE_float('wu', 1, 'Consistency weight.')
flags.DEFINE_float('wd', 0.0005, 'Weight decay.')
flags.DEFINE_float('we', 0, 'Entropy minimization weight.')
flags.DEFINE_float('ema', 0.999, 'Exponential moving average of params.')
flags.DEFINE_float('confidence', 0.95, 'Confidence threshold.')
flags.DEFINE_float('temperature', 1, 'Softmax sharpening temperature.')
flags.DEFINE_integer('scales', 0, 'Number of 2x2 downscalings in the classifier.')
flags.DEFINE_integer('filters', 32, 'Filter size of convolutions.')
flags.DEFINE_integer('repeat', 4, 'Number of residual layers per stage.')
flags.DEFINE_integer('tsa_pos', 8, 'TSA change rate.')
flags.DEFINE_integer('uratio', 7, 'Unlabeled batch size ratio.')
flags.DEFINE_enum('tsa', 'no', UDA.TSA_MODES, 'TSA mode.')
FLAGS.set_default('augment', 'd.d.rac')
FLAGS.set_default('dataset', 'cifar10.3@250-1')
FLAGS.set_default('batch', 64)
FLAGS.set_default('lr', 0.03)
FLAGS.set_default('train_kimg', 1 << 16)
app.run(main)