def setUp(self):
paddle.enable_static()
self.init_test_case()
port = np.random.randint(8337, 8773)
self.sanas = SANAS(configs=self.configs,
server_addr=("", port),
save_checkpoint=None)
def start_client(configs, addr, port):
client_sanas = SANAS(configs=configs,
server_addr=(addr, port),
save_checkpoint=None,
is_server=False)
for _ in range(2):
arch = client_sanas.next_archs()[0]
time.sleep(1)
client_sanas.reward(0.1)
def test_nas(self):
factory = SearchSpaceFactory()
config0 = {'input_size': 224, 'output_size': 7, 'block_num': 5}
config1 = {'input_size': 7, 'output_size': 1, 'block_num': 2}
configs = [('MobileNetV2Space', config0), ('ResNetSpace', config1)]
space = factory.get_search_space([('MobileNetV2Space', config0)])
origin_arch = space.token2arch()[0]
main_program = fluid.Program()
s_program = fluid.Program()
with fluid.program_guard(main_program, s_program):
input = fluid.data(name="input",
shape=[None, 3, 224, 224],
dtype="float32")
origin_arch(input)
base_flops = flops(main_program)
search_steps = 3
sa_nas = SANAS(configs,
search_steps=search_steps,
server_addr=("", 0),
is_server=True)
for i in range(search_steps):
archs = sa_nas.next_archs()
main_program = fluid.Program()
s_program = fluid.Program()
with fluid.program_guard(main_program, s_program):
input = fluid.data(name="input",
shape=[None, 3, 224, 224],
dtype="float32")
archs[0](input)
sa_nas.reward(1)
self.assertTrue(flops(main_program) < base_flops)
def test_median_stop(self):
config = [('MobileNetV2Space')]
sanas = SANAS(config, server_addr=("", 8732), save_checkpoint=None)
earlystop = MedianStop(sanas, 2)
avg_loss = 1.0
for step in range(steps):
status = earlystop.get_status(step, avg_loss, epochs)
self.assertTrue(status, 'GOOD')
avg_loss = 0.5
for step in range(steps):
status = earlystop.get_status(step, avg_loss, epochs)
if step < 2:
self.assertTrue(status, 'GOOD')
else:
self.assertTrue(status, 'BAD')
def main():
env = os.environ
FLAGS.dist = 'PADDLE_TRAINER_ID' in env and 'PADDLE_TRAINERS_NUM' in env
if FLAGS.dist:
trainer_id = int(env['PADDLE_TRAINER_ID'])
import random
local_seed = (99 + trainer_id)
random.seed(local_seed)
np.random.seed(local_seed)
cfg = load_config(FLAGS.config)
if 'architecture' in cfg:
main_arch = cfg.architecture
else:
raise ValueError("'architecture' not specified in config file.")
merge_config(FLAGS.opt)
if 'log_iter' not in cfg:
cfg.log_iter = 20
# check if set use_gpu=True in paddlepaddle cpu version
check_gpu(cfg.use_gpu)
# check if paddlepaddle version is satisfied
check_version()
if cfg.use_gpu:
devices_num = fluid.core.get_cuda_device_count()
else:
devices_num = int(os.environ.get('CPU_NUM', 1))
if 'FLAGS_selected_gpus' in env:
device_id = int(env['FLAGS_selected_gpus'])
else:
device_id = 0
place = fluid.CUDAPlace(device_id) if cfg.use_gpu else fluid.CPUPlace()
exe = fluid.Executor(place)
lr_builder = create('LearningRate')
optim_builder = create('OptimizerBuilder')
# add NAS
config = ([(cfg.search_space)])
server_address = (cfg.server_ip, cfg.server_port)
load_checkpoint = FLAGS.resume_checkpoint if FLAGS.resume_checkpoint else None
sa_nas = SANAS(config,
server_addr=server_address,
init_temperature=cfg.init_temperature,
reduce_rate=cfg.reduce_rate,
search_steps=cfg.search_steps,
save_checkpoint=cfg.save_dir,
load_checkpoint=load_checkpoint,
is_server=cfg.is_server)
start_iter = 0
train_reader = create_reader(cfg.TrainReader,
(cfg.max_iters - start_iter) * devices_num,
cfg)
eval_reader = create_reader(cfg.EvalReader)
constraint = create('Constraint')
for step in range(cfg.search_steps):
logger.info('----->>> search step: {} <<<------'.format(step))
archs = sa_nas.next_archs()[0]
# build program
startup_prog = fluid.Program()
train_prog = fluid.Program()
with fluid.program_guard(train_prog, startup_prog):
with fluid.unique_name.guard():
model = create(main_arch)
if FLAGS.fp16:
assert (getattr(model.backbone, 'norm_type', None)
!= 'affine_channel'), \
'--fp16 currently does not support affine channel, ' \
' please modify backbone settings to use batch norm'
with mixed_precision_context(FLAGS.loss_scale,
FLAGS.fp16) as ctx:
inputs_def = cfg['TrainReader']['inputs_def']
feed_vars, train_loader = model.build_inputs(**inputs_def)
train_fetches = archs(feed_vars, 'train', cfg)
loss = train_fetches['loss']
if FLAGS.fp16:
loss *= ctx.get_loss_scale_var()
lr = lr_builder()
optimizer = optim_builder(lr)
optimizer.minimize(loss)
if FLAGS.fp16:
loss /= ctx.get_loss_scale_var()
current_constraint = constraint.compute_constraint(train_prog)
logger.info('current steps: {}, constraint {}'.format(
step, current_constraint))
if (constraint.max_constraint != None
and current_constraint > constraint.max_constraint) or (
constraint.min_constraint != None
and current_constraint < constraint.min_constraint):
continue
# parse train fetches
train_keys, train_values, _ = parse_fetches(train_fetches)
train_values.append(lr)
if FLAGS.eval:
eval_prog = fluid.Program()
with fluid.program_guard(eval_prog, startup_prog):
with fluid.unique_name.guard():
model = create(main_arch)
inputs_def = cfg['EvalReader']['inputs_def']
feed_vars, eval_loader = model.build_inputs(**inputs_def)
fetches = archs(feed_vars, 'eval', cfg)
eval_prog = eval_prog.clone(True)
eval_loader.set_sample_list_generator(eval_reader, place)
extra_keys = ['im_id', 'im_shape', 'gt_bbox']
eval_keys, eval_values, eval_cls = parse_fetches(
fetches, eval_prog, extra_keys)
# compile program for multi-devices
build_strategy = fluid.BuildStrategy()
build_strategy.fuse_all_optimizer_ops = False
build_strategy.fuse_elewise_add_act_ops = True
exec_strategy = fluid.ExecutionStrategy()
# iteration number when CompiledProgram tries to drop local execution scopes.
# Set it to be 1 to save memory usages, so that unused variables in
# local execution scopes can be deleted after each iteration.
exec_strategy.num_iteration_per_drop_scope = 1
if FLAGS.dist:
dist_utils.prepare_for_multi_process(exe, build_strategy,
startup_prog, train_prog)
exec_strategy.num_threads = 1
exe.run(startup_prog)
compiled_train_prog = fluid.CompiledProgram(
train_prog).with_data_parallel(loss_name=loss.name,
build_strategy=build_strategy,
exec_strategy=exec_strategy)
if FLAGS.eval:
compiled_eval_prog = fluid.compiler.CompiledProgram(eval_prog)
train_loader.set_sample_list_generator(train_reader, place)
train_stats = TrainingStats(cfg.log_smooth_window, train_keys)
train_loader.start()
end_time = time.time()
cfg_name = os.path.basename(FLAGS.config).split('.')[0]
save_dir = os.path.join(cfg.save_dir, cfg_name)
time_stat = deque(maxlen=cfg.log_smooth_window)
ap = 0
for it in range(start_iter, cfg.max_iters):
start_time = end_time
end_time = time.time()
time_stat.append(end_time - start_time)
time_cost = np.mean(time_stat)
eta_sec = (cfg.max_iters - it) * time_cost
eta = str(datetime.timedelta(seconds=int(eta_sec)))
outs = exe.run(compiled_train_prog, fetch_list=train_values)
stats = {
k: np.array(v).mean()
for k, v in zip(train_keys, outs[:-1])
}
train_stats.update(stats)
logs = train_stats.log()
if it % cfg.log_iter == 0 and (not FLAGS.dist or trainer_id == 0):
strs = 'iter: {}, lr: {:.6f}, {}, time: {:.3f}, eta: {}'.format(
it, np.mean(outs[-1]), logs, time_cost, eta)
logger.info(strs)
if (it > 0 and it == cfg.max_iters - 1) and (not FLAGS.dist
or trainer_id == 0):
save_name = str(
it) if it != cfg.max_iters - 1 else "model_final"
checkpoint.save(exe, train_prog,
os.path.join(save_dir, save_name))
if FLAGS.eval:
# evaluation
results = eval_run(exe, compiled_eval_prog, eval_loader,
eval_keys, eval_values, eval_cls)
ap = calculate_ap_py(results)
train_loader.reset()
eval_loader.reset()
logger.info('rewards: ap is {}'.format(ap))
sa_nas.reward(float(ap))
current_best_tokens = sa_nas.current_info()['best_tokens']
logger.info("All steps end, the best BlazeFace-NAS structure is: ")
sa_nas.tokens2arch(current_best_tokens)
def final_test(config, args, image_size, token=None):
assert token != None, "If you want to start a final experiment, you must input a token."
sa_nas = SANAS(
config, server_addr=(args.server_address, args.port), is_server=True)
image_shape = [3, image_size, image_size]
archs = sa_nas.tokens2arch(token)[0]
train_program = fluid.Program()
test_program = fluid.Program()
startup_program = fluid.Program()
train_fetch_list, train_loader = build_program(
train_program,
startup_program,
image_shape,
archs,
args,
is_train=True)
current_params = count_parameters_in_MB(
train_program.global_block().all_parameters(), 'cifar10')
_logger.info('current_params: {}M'.format(current_params))
test_fetch_list, test_loader = build_program(
test_program,
startup_program,
image_shape,
archs,
args,
is_train=False)
test_program = test_program.clone(for_test=True)
place = fluid.CUDAPlace(0) if args.use_gpu else fluid.CPUPlace()
exe = fluid.Executor(place)
exe.run(startup_program)
train_reader = reader.train_valid(
batch_size=args.batch_size, is_train=True, is_shuffle=True, args=args)
test_reader = reader.train_valid(
batch_size=args.batch_size,
is_train=False,
is_shuffle=False,
args=args)
train_loader.set_batch_generator(train_reader, places=place)
test_loader.set_batch_generator(test_reader, places=place)
build_strategy = fluid.BuildStrategy()
train_compiled_program = fluid.CompiledProgram(
train_program).with_data_parallel(
loss_name=train_fetch_list[0].name, build_strategy=build_strategy)
valid_top1_list = []
for epoch_id in range(args.retain_epoch):
train_top1 = train(train_compiled_program, exe, epoch_id, train_loader,
train_fetch_list, args)
_logger.info("TRAIN: Epoch {}, train_acc {:.6f}".format(epoch_id,
train_top1))
valid_top1 = valid(test_program, exe, epoch_id, test_loader,
test_fetch_list, args)
_logger.info("TEST: Epoch {}, valid_acc {:.6f}".format(epoch_id,
valid_top1))
valid_top1_list.append(valid_top1)
output_dir = os.path.join('darts_output', str(epoch_id))
if not os.path.exists(output_dir):
os.makedirs(output_dir)
fluid.io.save_persistables(exe, output_dir, main_program=train_program)
def search(config, args, image_size, is_server=True):
if is_server:
### start a server and a client
sa_nas = SANAS(
config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=True)
else:
### start a client
sa_nas = SANAS(
config,
server_addr=(args.server_address, args.port),
init_temperature=init_temperature,
is_server=False)
image_shape = [3, image_size, image_size]
for step in range(args.search_steps):
archs = sa_nas.next_archs()[0]
train_program = fluid.Program()
test_program = fluid.Program()
startup_program = fluid.Program()
train_fetch_list, train_loader = build_program(
train_program,
startup_program,
image_shape,
archs,
args,
is_train=True)
current_params = count_parameters_in_MB(
train_program.global_block().all_parameters(), 'cifar10')
_logger.info('step: {}, current_params: {}M'.format(step,
current_params))
if current_params > float(3.77):
continue
test_fetch_list, test_loader = build_program(
test_program,
startup_program,
image_shape,
archs,
args,
is_train=False)
test_program = test_program.clone(for_test=True)
place = fluid.CUDAPlace(0) if args.use_gpu else fluid.CPUPlace()
exe = fluid.Executor(place)
exe.run(startup_program)
train_reader = reader.train_valid(
batch_size=args.batch_size, is_train=True, is_shuffle=True)
test_reader = reader.train_valid(
batch_size=args.batch_size, is_train=False, is_shuffle=False)
train_loader.set_batch_generator(train_reader, places=place)
test_loader.set_batch_generator(test_reader, places=place)
build_strategy = fluid.BuildStrategy()
train_compiled_program = fluid.CompiledProgram(
train_program).with_data_parallel(
loss_name=train_fetch_list[0].name,
build_strategy=build_strategy)
valid_top1_list = []
for epoch_id in range(args.retain_epoch):
train_top1 = train(train_compiled_program, exe, epoch_id,
train_loader, train_fetch_list, args)
_logger.info("TRAIN: step: {}, Epoch {}, train_acc {:.6f}".format(
step, epoch_id, train_top1))
valid_top1 = valid(test_program, exe, epoch_id, test_loader,
test_fetch_list, args)
_logger.info("TEST: Epoch {}, valid_acc {:.6f}".format(epoch_id,
valid_top1))
valid_top1_list.append(valid_top1)
sa_nas.reward(float(valid_top1_list[-1] + valid_top1_list[-2]) / 2)
def search_mobilenetv2_block(config, args, image_size):
image_shape = [3, image_size, image_size]
if args.is_server:
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=True)
else:
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=False)
for step in range(args.search_steps):
archs = sa_nas.next_archs()[0]
train_program = fluid.Program()
test_program = fluid.Program()
startup_program = fluid.Program()
with fluid.program_guard(train_program, startup_program):
train_loader, data, label = create_data_loader(image_shape)
data = conv_bn_layer(input=data,
num_filters=32,
filter_size=3,
stride=2,
padding='SAME',
act='relu6',
name='mobilenetv2_conv1')
data = archs(data)[0]
data = conv_bn_layer(input=data,
num_filters=1280,
filter_size=1,
stride=1,
padding='SAME',
act='relu6',
name='mobilenetv2_last_conv')
data = fluid.layers.pool2d(input=data,
pool_size=7,
pool_stride=1,
pool_type='avg',
global_pooling=True,
name='mobilenetv2_last_pool')
output = fluid.layers.fc(
input=data,
size=args.class_dim,
param_attr=ParamAttr(name='mobilenetv2_fc_weights'),
bias_attr=ParamAttr(name='mobilenetv2_fc_offset'))
softmax_out = fluid.layers.softmax(input=output, use_cudnn=False)
cost = fluid.layers.cross_entropy(input=softmax_out, label=label)
avg_cost = fluid.layers.mean(cost)
acc_top1 = fluid.layers.accuracy(input=softmax_out,
label=label,
k=1)
acc_top5 = fluid.layers.accuracy(input=softmax_out,
label=label,
k=5)
test_program = train_program.clone(for_test=True)
optimizer = fluid.optimizer.Momentum(
learning_rate=0.1,
momentum=0.9,
regularization=fluid.regularizer.L2Decay(1e-4))
optimizer.minimize(avg_cost)
current_flops = flops(train_program)
print('step: {}, current_flops: {}'.format(step, current_flops))
if current_flops > int(321208544):
continue
place = fluid.CUDAPlace(0) if args.use_gpu else fluid.CPUPlace()
exe = fluid.Executor(place)
exe.run(startup_program)
if args.data == 'cifar10':
train_reader = paddle.fluid.io.batch(paddle.reader.shuffle(
paddle.dataset.cifar.train10(cycle=False), buf_size=1024),
batch_size=args.batch_size,
drop_last=True)
test_reader = paddle.fluid.io.batch(
paddle.dataset.cifar.test10(cycle=False),
batch_size=args.batch_size,
drop_last=False)
elif args.data == 'imagenet':
train_reader = paddle.fluid.io.batch(imagenet_reader.train(),
batch_size=args.batch_size,
drop_last=True)
test_reader = paddle.fluid.io.batch(imagenet_reader.val(),
batch_size=args.batch_size,
drop_last=False)
test_loader, _, _ = create_data_loader(image_shape)
train_loader.set_sample_list_generator(
train_reader,
places=fluid.cuda_places() if args.use_gpu else fluid.cpu_places())
test_loader.set_sample_list_generator(test_reader, places=place)
build_strategy = fluid.BuildStrategy()
train_compiled_program = fluid.CompiledProgram(
train_program).with_data_parallel(loss_name=avg_cost.name,
build_strategy=build_strategy)
for epoch_id in range(args.retain_epoch):
for batch_id, data in enumerate(train_loader()):
fetches = [avg_cost.name]
s_time = time.time()
outs = exe.run(train_compiled_program,
feed=data,
fetch_list=fetches)[0]
batch_time = time.time() - s_time
if batch_id % 10 == 0:
_logger.info(
'TRAIN: steps: {}, epoch: {}, batch: {}, cost: {}, batch_time: {}ms'
.format(step, epoch_id, batch_id, outs[0], batch_time))
reward = []
for batch_id, data in enumerate(test_loader()):
test_fetches = [avg_cost.name, acc_top1.name, acc_top5.name]
batch_reward = exe.run(test_program,
feed=data,
fetch_list=test_fetches)
reward_avg = np.mean(np.array(batch_reward), axis=1)
reward.append(reward_avg)
_logger.info(
'TEST: step: {}, batch: {}, avg_cost: {}, acc_top1: {}, acc_top5: {}'
.format(step, batch_id, batch_reward[0], batch_reward[1],
batch_reward[2]))
finally_reward = np.mean(np.array(reward), axis=0)
_logger.info(
'FINAL TEST: avg_cost: {}, acc_top1: {}, acc_top5: {}'.format(
finally_reward[0], finally_reward[1], finally_reward[2]))
sa_nas.reward(float(finally_reward[1]))
def search_mobilenetv2(config, args, image_size, is_server=True):
if is_server:
### start a server and a client
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=True)
else:
### start a client
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=False)
image_shape = [3, image_size, image_size]
for step in range(args.search_steps):
archs = sa_nas.next_archs()[0]
train_program = fluid.Program()
test_program = fluid.Program()
startup_program = fluid.Program()
train_loader, avg_cost, acc_top1, acc_top5 = build_program(
train_program, startup_program, image_shape, archs, args)
current_flops = flops(train_program)
print('step: {}, current_flops: {}'.format(step, current_flops))
if current_flops > int(321208544):
continue
test_loader, test_avg_cost, test_acc_top1, test_acc_top5 = build_program(
test_program,
startup_program,
image_shape,
archs,
args,
is_test=True)
test_program = test_program.clone(for_test=True)
place = fluid.CUDAPlace(0) if args.use_gpu else fluid.CPUPlace()
exe = fluid.Executor(place)
exe.run(startup_program)
if args.data == 'cifar10':
train_reader = paddle.batch(paddle.reader.shuffle(
paddle.dataset.cifar.train10(cycle=False), buf_size=1024),
batch_size=args.batch_size,
drop_last=True)
test_reader = paddle.batch(
paddle.dataset.cifar.test10(cycle=False),
batch_size=args.batch_size,
drop_last=False)
elif args.data == 'imagenet':
train_reader = paddle.batch(imagenet_reader.train(),
batch_size=args.batch_size,
drop_last=True)
test_reader = paddle.batch(imagenet_reader.val(),
batch_size=args.batch_size,
drop_last=False)
train_loader.set_sample_list_generator(
train_reader,
places=fluid.cuda_places() if args.use_gpu else fluid.cpu_places())
test_loader.set_sample_list_generator(test_reader, places=place)
build_strategy = fluid.BuildStrategy()
train_compiled_program = fluid.CompiledProgram(
train_program).with_data_parallel(loss_name=avg_cost.name,
build_strategy=build_strategy)
for epoch_id in range(args.retain_epoch):
for batch_id, data in enumerate(train_loader()):
fetches = [avg_cost.name]
s_time = time.time()
outs = exe.run(train_compiled_program,
feed=data,
fetch_list=fetches)[0]
batch_time = time.time() - s_time
if batch_id % 10 == 0:
_logger.info(
'TRAIN: steps: {}, epoch: {}, batch: {}, cost: {}, batch_time: {}ms'
.format(step, epoch_id, batch_id, outs[0], batch_time))
reward = []
for batch_id, data in enumerate(test_loader()):
test_fetches = [
test_avg_cost.name, test_acc_top1.name, test_acc_top5.name
]
batch_reward = exe.run(test_program,
feed=data,
fetch_list=test_fetches)
reward_avg = np.mean(np.array(batch_reward), axis=1)
reward.append(reward_avg)
_logger.info(
'TEST: step: {}, batch: {}, avg_cost: {}, acc_top1: {}, acc_top5: {}'
.format(step, batch_id, batch_reward[0], batch_reward[1],
batch_reward[2]))
finally_reward = np.mean(np.array(reward), axis=0)
_logger.info(
'FINAL TEST: avg_cost: {}, acc_top1: {}, acc_top5: {}'.format(
finally_reward[0], finally_reward[1], finally_reward[2]))
sa_nas.reward(float(finally_reward[1]))
class TestSANAS(unittest.TestCase):
def setUp(self):
self.init_test_case()
port = np.random.randint(8337, 8773)
self.sanas = SANAS(configs=self.configs,
server_addr=("", port),
save_checkpoint=None)
def init_test_case(self):
self.configs = [('MobileNetV2BlockSpace', {'block_mask': [0]})]
self.filter_num = np.array([
3, 4, 8, 12, 16, 24, 32, 48, 64, 80, 96, 128, 144, 160, 192, 224,
256, 320, 384, 512
])
self.k_size = np.array([3, 5])
self.multiply = np.array([1, 2, 3, 4, 5, 6])
self.repeat = np.array([1, 2, 3, 4, 5, 6])
def check_chnum_convnum(self, program):
current_tokens = self.sanas.current_info()['current_tokens']
channel_exp = self.multiply[current_tokens[0]]
filter_num = self.filter_num[current_tokens[1]]
repeat_num = self.repeat[current_tokens[2]]
conv_list, ch_pro = compute_op_num(program)
### assert conv number
self.assertTrue((repeat_num * 3) == len(
conv_list
), "the number of conv is NOT match, the number compute from token: {}, actual conv number: {}"
.format(repeat_num * 3, len(conv_list)))
### assert number of channels
ch_token = []
init_ch_num = 32
for i in range(repeat_num):
ch_token.append(init_ch_num * channel_exp)
ch_token.append(init_ch_num * channel_exp)
ch_token.append(filter_num)
init_ch_num = filter_num
self.assertTrue(
str(ch_token) == str(ch_pro),
"channel num is WRONG, channel num from token is {}, channel num come fom program is {}"
.format(str(ch_token), str(ch_pro)))
def test_all_function(self):
### unittest for next_archs
next_program = fluid.Program()
startup_program = fluid.Program()
token2arch_program = fluid.Program()
with fluid.program_guard(next_program, startup_program):
inputs = fluid.data(name='input',
shape=[None, 3, 32, 32],
dtype='float32')
archs = self.sanas.next_archs()
for arch in archs:
output = arch(inputs)
inputs = output
self.check_chnum_convnum(next_program)
### unittest for reward
self.assertTrue(self.sanas.reward(float(1.0)), "reward is False")
### uniitest for tokens2arch
with fluid.program_guard(token2arch_program, startup_program):
inputs = fluid.data(name='input',
shape=[None, 3, 32, 32],
dtype='float32')
arch = self.sanas.tokens2arch(
self.sanas.current_info()['current_tokens'])
for arch in archs:
output = arch(inputs)
inputs = output
self.check_chnum_convnum(token2arch_program)
### unittest for current_info
current_info = self.sanas.current_info()
self.assertTrue(
isinstance(current_info, dict),
"the type of current info must be dict, but now is {}".format(
type(current_info)))
def search_mobilenetv2(config, args, image_size, is_server=True):
image_shape = [3, image_size, image_size]
if args.data == 'cifar10':
transform = T.Compose([T.Transpose(), T.Normalize([127.5], [127.5])])
train_dataset = paddle.vision.datasets.Cifar10(mode='train',
transform=transform,
backend='cv2')
val_dataset = paddle.vision.datasets.Cifar10(mode='test',
transform=transform,
backend='cv2')
elif args.data == 'imagenet':
train_dataset = imagenet_reader.ImageNetDataset(mode='train')
val_dataset = imagenet_reader.ImageNetDataset(mode='val')
places = static.cuda_places() if args.use_gpu else static.cpu_places()
place = places[0]
if is_server:
### start a server and a client
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=True)
else:
### start a client
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=False)
for step in range(args.search_steps):
archs = sa_nas.next_archs()[0]
train_program = static.Program()
test_program = static.Program()
startup_program = static.Program()
train_loader, avg_cost, acc_top1, acc_top5 = build_program(
train_program, startup_program, image_shape, train_dataset, archs,
args, places)
current_flops = flops(train_program)
print('step: {}, current_flops: {}'.format(step, current_flops))
if current_flops > int(321208544):
continue
test_loader, test_avg_cost, test_acc_top1, test_acc_top5 = build_program(
test_program,
startup_program,
image_shape,
val_dataset,
archs,
args,
place,
is_test=True)
test_program = test_program.clone(for_test=True)
exe = static.Executor(place)
exe.run(startup_program)
build_strategy = static.BuildStrategy()
train_compiled_program = static.CompiledProgram(
train_program).with_data_parallel(loss_name=avg_cost.name,
build_strategy=build_strategy)
for epoch_id in range(args.retain_epoch):
for batch_id, data in enumerate(train_loader()):
fetches = [avg_cost.name]
s_time = time.time()
outs = exe.run(train_compiled_program,
feed=data,
fetch_list=fetches)[0]
batch_time = time.time() - s_time
if batch_id % 10 == 0:
_logger.info(
'TRAIN: steps: {}, epoch: {}, batch: {}, cost: {}, batch_time: {}ms'
.format(step, epoch_id, batch_id, outs[0], batch_time))
reward = []
for batch_id, data in enumerate(test_loader()):
test_fetches = [
test_avg_cost.name, test_acc_top1.name, test_acc_top5.name
]
batch_reward = exe.run(test_program,
feed=data,
fetch_list=test_fetches)
reward_avg = np.mean(np.array(batch_reward), axis=1)
reward.append(reward_avg)
_logger.info(
'TEST: step: {}, batch: {}, avg_cost: {}, acc_top1: {}, acc_top5: {}'
.format(step, batch_id, batch_reward[0], batch_reward[1],
batch_reward[2]))
finally_reward = np.mean(np.array(reward), axis=0)
_logger.info(
'FINAL TEST: avg_cost: {}, acc_top1: {}, acc_top5: {}'.format(
finally_reward[0], finally_reward[1], finally_reward[2]))
sa_nas.reward(float(finally_reward[1]))
def search_mobilenetv2_block(config, args, image_size):
image_shape = [3, image_size, image_size]
transform = T.Compose([T.Transpose(), T.Normalize([127.5], [127.5])])
if args.data == 'cifar10':
train_dataset = paddle.vision.datasets.Cifar10(mode='train',
transform=transform,
backend='cv2')
val_dataset = paddle.vision.datasets.Cifar10(mode='test',
transform=transform,
backend='cv2')
elif args.data == 'imagenet':
train_dataset = imagenet_reader.ImageNetDataset(mode='train')
val_dataset = imagenet_reader.ImageNetDataset(mode='val')
places = static.cuda_places() if args.use_gpu else static.cpu_places()
place = places[0]
if args.is_server:
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=True)
else:
sa_nas = SANAS(config,
server_addr=(args.server_address, args.port),
search_steps=args.search_steps,
is_server=False)
for step in range(args.search_steps):
archs = sa_nas.next_archs()[0]
train_program = static.Program()
test_program = static.Program()
startup_program = static.Program()
with static.program_guard(train_program, startup_program):
data_shape = [None] + image_shape
data = static.data(name='data', shape=data_shape, dtype='float32')
label = static.data(name='label', shape=[None, 1], dtype='int64')
if args.data == 'cifar10':
paddle.assign(paddle.reshape(label, [-1, 1]), label)
train_loader = paddle.io.DataLoader(train_dataset,
places=places,
feed_list=[data, label],
drop_last=True,
batch_size=args.batch_size,
return_list=False,
shuffle=True,
use_shared_memory=True,
num_workers=4)
val_loader = paddle.io.DataLoader(val_dataset,
places=place,
feed_list=[data, label],
drop_last=False,
batch_size=args.batch_size,
return_list=False,
shuffle=False)
data = conv_bn_layer(input=data,
num_filters=32,
filter_size=3,
stride=2,
padding='SAME',
act='relu6',
name='mobilenetv2_conv1')
data = archs(data)[0]
data = conv_bn_layer(input=data,
num_filters=1280,
filter_size=1,
stride=1,
padding='SAME',
act='relu6',
name='mobilenetv2_last_conv')
data = F.adaptive_avg_pool2d(data,
output_size=[1, 1],
name='mobilenetv2_last_pool')
output = static.nn.fc(
x=data,
size=args.class_dim,
weight_attr=ParamAttr(name='mobilenetv2_fc_weights'),
bias_attr=ParamAttr(name='mobilenetv2_fc_offset'))
softmax_out = F.softmax(output)
cost = F.cross_entropy(softmax_out, label=label)
avg_cost = paddle.mean(cost)
acc_top1 = paddle.metric.accuracy(input=softmax_out,
label=label,
k=1)
acc_top5 = paddle.metric.accuracy(input=softmax_out,
label=label,
k=5)
test_program = train_program.clone(for_test=True)
optimizer = paddle.optimizer.Momentum(
learning_rate=0.1,
momentum=0.9,
weight_decay=paddle.regularizer.L2Decay(1e-4))
optimizer.minimize(avg_cost)
current_flops = flops(train_program)
print('step: {}, current_flops: {}'.format(step, current_flops))
if current_flops > int(321208544):
continue
exe = static.Executor(place)
exe.run(startup_program)
build_strategy = static.BuildStrategy()
train_compiled_program = static.CompiledProgram(
train_program).with_data_parallel(loss_name=avg_cost.name,
build_strategy=build_strategy)
for epoch_id in range(args.retain_epoch):
for batch_id, data in enumerate(train_loader()):
fetches = [avg_cost.name]
s_time = time.time()
outs = exe.run(train_compiled_program,
feed=data,
fetch_list=fetches)[0]
batch_time = time.time() - s_time
if batch_id % 10 == 0:
_logger.info(
'TRAIN: steps: {}, epoch: {}, batch: {}, cost: {}, batch_time: {}ms'
.format(step, epoch_id, batch_id, outs[0], batch_time))
reward = []
for batch_id, data in enumerate(val_loader()):
test_fetches = [avg_cost.name, acc_top1.name, acc_top5.name]
batch_reward = exe.run(test_program,
feed=data,
fetch_list=test_fetches)
reward_avg = np.mean(np.array(batch_reward), axis=1)
reward.append(reward_avg)
_logger.info(
'TEST: step: {}, batch: {}, avg_cost: {}, acc_top1: {}, acc_top5: {}'
.format(step, batch_id, batch_reward[0], batch_reward[1],
batch_reward[2]))
finally_reward = np.mean(np.array(reward), axis=0)
_logger.info(
'FINAL TEST: avg_cost: {}, acc_top1: {}, acc_top5: {}'.format(
finally_reward[0], finally_reward[1], finally_reward[2]))
sa_nas.reward(float(finally_reward[1]))
def start_server(configs, port):
server_sanas = SANAS(configs=configs,
server_addr=("", port),
save_checkpoint=None)
server_sanas.next_archs()[0]
return server_sanas