def handle(self, *args, **options):
with open('device_map.csv', 'r') as csvfile:
reader = csv.reader(csvfile, delimiter=',', quotechar='|')
next(reader, None)
for r in reader:
brand = Brand.objects.filter(name=r[0])
if brand:
brand = brand.first()
else:
brand = Brand(name=r[0])
brand.save()
model = Model(name=r[1], number=r[2], brand=brand)
model.save()
def __init__(self):
#Only Model will initialize
Model.__init__(self, self.__defaults())
BaseType.__init__(self)
def __init__(self):
object.__init__(self)
Model.__init__(self, self.__defaults())
def __init__(self):
Model.__init__(self, self.__defaults())
def __init__(self):
Model.__init__(self, self.__defaults())
BaseWidget.__init__(self)
def train():
""" 训练 """
resume = TRAIN_HYPER_PARAMS["resume"]
num_epochs = TRAIN_HYPER_PARAMS["num_epochs"]
keep_prob = TRAIN_HYPER_PARAMS["keep_prob"]
class_per_batch = TRAIN_HYPER_PARAMS["class_per_batch"]
shoe_per_class = TRAIN_HYPER_PARAMS["shoe_per_class"]
img_per_shoe = TRAIN_HYPER_PARAMS["img_per_shoe"]
save_step = TRAIN_HYPER_PARAMS["save_step"]
test_step = TRAIN_HYPER_PARAMS["test_step"]
train_test = TRAIN_HYPER_PARAMS["train_test"]
dev_test = TRAIN_HYPER_PARAMS["dev_test"]
max_mini_batch_size = class_per_batch * \
shoe_per_class * (shoe_per_class-1) / 2
# GPU Config
config = tf.ConfigProto()
if GPU.enable:
config.gpu_options.per_process_gpu_memory_fraction = GPU.memory_fraction
config.gpu_options.allow_growth = True
os.environ["CUDA_VISIBLE_DEVICES"] = ", ".join(
map(lambda x: str(x), GPU.devices))
else:
os.environ["CUDA_VISIBLE_DEVICES"] = "-1"
model = Model(TRAIN_HYPER_PARAMS)
recorder = Recorder(RECORDER_PATH, resume=resume)
recorder.upload_params(TRAIN_HYPER_PARAMS)
# train data
data_set = data_import(augment=ALL)
img_arrays = data_set["img_arrays"]
indices = data_set["indices"]
train_size = len(indices)
# test data
if train_test or dev_test:
test_img_arrays, test_data_map, _ = test_data_import(
augment=[TRANSPOSE], action_type="train")
train_scope_length = len(test_data_map["train"][0]["scope_indices"])
train_num_augment = len(test_data_map["train"][0]["indices"])
dev_scope_length = len(test_data_map["dev"][0]["scope_indices"])
dev_num_augment = len(test_data_map["dev"][0]["indices"])
graph = tf.Graph()
with graph.as_default():
tf.set_random_seed(SEED)
if resume:
model.import_meta_graph()
model.get_ops_from_graph(graph)
else:
model.init_ops()
# test 计算图
if train_test or dev_test:
test_embeddings_length = len(test_img_arrays)
if train_test:
model.init_test_ops("train", train_scope_length, train_num_augment,
test_embeddings_length)
if dev_test:
model.init_test_ops("dev", dev_scope_length, dev_num_augment,
test_embeddings_length)
with tf.Session(graph=graph, config=config) as sess:
if resume:
model.load(sess)
print("成功恢复模型 {}".format(model.name))
else:
model.init_saver()
sess.run(tf.global_variables_initializer())
model.update_learning_rate(sess)
clock = time.time()
for epoch in range(recorder.checkpoint + 1, num_epochs + 1):
recorder.update_checkpoint(epoch)
# train
train_costs = []
triplet_cache = []
for batch_index, triplets in BatchLoader(
model,
indices,
class_per_batch=class_per_batch,
shoe_per_class=shoe_per_class,
img_per_shoe=img_per_shoe,
img_arrays=img_arrays,
sess=sess):
# 小数据 cache 机制
if len(triplets) == 0:
continue
elif len(triplets) + len(
triplet_cache) <= max_mini_batch_size // 2:
triplet_cache.extend(triplets)
continue
elif max_mini_batch_size // 2 < len(triplets) + len(
triplet_cache) <= max_mini_batch_size:
triplets.extend(triplet_cache)
triplet_cache.clear()
triplet_list = [list(line) for line in zip(*triplets)]
mini_batch_size = len(triplet_list[0])
_, temp_cost = sess.run(
[model.ops["train_step"], model.ops["loss"]],
feed_dict={
model.ops["A"]:
np.divide(img_arrays[triplet_list[0]],
127.5,
dtype=np.float32) - 1,
model.ops["P"]:
np.divide(img_arrays[triplet_list[1]],
127.5,
dtype=np.float32) - 1,
model.ops["N"]:
np.divide(img_arrays[triplet_list[2]],
127.5,
dtype=np.float32) - 1,
model.ops["is_training"]:
True,
model.ops["keep_prob"]:
keep_prob
})
temp_cost /= max_mini_batch_size
print("{} mini-batch > {}/{} size: {} cost: {} ".format(
epoch, batch_index, train_size, mini_batch_size,
temp_cost),
end="\r")
train_costs.append(temp_cost)
train_cost = sum(train_costs) / len(train_costs)
# test
log_str = "{}/{} {} train cost is {}".format(
epoch, num_epochs,
time.strftime("%Y-%m-%d %H:%M:%S", time.localtime()),
train_cost)
if epoch % test_step == 0:
train_top_1_acc, train_top_5_acc, dev_top_1_acc, dev_top_5_acc = "", "", "", ""
if train_test or dev_test:
test_embeddings = model.compute_embeddings(
test_img_arrays, sess=sess)
if train_test:
_, train_top_1_acc, train_top_5_acc = data_test(
test_data_map,
"train",
test_embeddings,
sess,
model,
log=False)
log_str += " train top-1:{:.2%} top-5:{:.2%}".format(
train_top_1_acc, train_top_5_acc)
if dev_test:
_, dev_top_1_acc, dev_top_5_acc = data_test(
test_data_map,
"dev",
test_embeddings,
sess,
model,
log=False)
log_str += " dev top-1:{:.2%} top-5:{:.2%}".format(
dev_top_1_acc, dev_top_5_acc)
# 预计完成时间
prec_time_stamp = (time.time() - clock) * \
((num_epochs - epoch) // test_step) + clock
clock = time.time()
log_str += " >> {} ".format(
time.strftime("%Y-%m-%d %H:%M:%S",
time.localtime(prec_time_stamp)))
recorder.record_item(epoch, [
train_top_1_acc, train_top_5_acc, dev_top_1_acc,
dev_top_5_acc
])
if epoch % save_step == 0:
model.save(sess)
recorder.save()
print(log_str)
def test():
""" 测试主函数 """
use_cache = TEST_PARAMS["use_cache"]
# 加载模型与数据
model = Model(TRAIN_HYPER_PARAMS)
sample_cacher = Cacher(SAMPLE_EMB_CACHE)
img_arrays, test_data_map, sample_length = test_data_import(
augment=[(TRANSPOSE, BILATERAL_BLUR)], action_type="test")
GLOBAL["img_arrays"] = img_arrays
scope_length = len(test_data_map["test"][0]["scope_indices"])
num_augment = len(test_data_map["test"][0]["indices"])
# GPU Config
config = tf.ConfigProto()
if GPU.enable:
config.gpu_options.per_process_gpu_memory_fraction = GPU.memory_fraction
config.gpu_options.allow_growth = True
os.environ["CUDA_VISIBLE_DEVICES"] = ", ".join(
map(lambda x: str(x), GPU.devices))
else:
os.environ["CUDA_VISIBLE_DEVICES"] = "-1"
# 启动 TF 计算图与会话
graph = tf.Graph()
with graph.as_default():
model.import_meta_graph()
with tf.Session(graph=graph, config=config) as sess:
model.load(sess)
clock = time.time()
model.get_ops_from_graph(graph)
# 计算嵌入
if use_cache and os.path.exists(SAMPLE_EMB_CACHE):
# 如果已经有编码过的样本嵌入则直接读取
sample_embs = sample_cacher.read()
shoeprint_embs = model.compute_embeddings(
img_arrays[sample_length:], sess=sess)
embeddings = np.concatenate((sample_embs, shoeprint_embs))
print("成功读取预编码模板")
else:
embeddings = model.compute_embeddings(img_arrays, sess=sess)
sample_embs = embeddings[:sample_length]
sample_cacher.save(sample_embs)
# 初始化测试计算图
embeddings_length = len(img_arrays)
model.init_test_ops("test", scope_length, num_augment,
embeddings_length)
# 测试数据
res, top_1_accuracy, top_5_accuracy = data_test(test_data_map,
"test",
embeddings,
sess,
model,
log=IS_LOG,
plot=IS_PLOT)
print("Top-1: {:.2%}, Top-5: {:.2%}".format(
top_1_accuracy, top_5_accuracy))
print("{:.2f}s".format(time.time() - clock))
# 将结果写入输出文件
with open(RESULT_FILE, "w") as f:
for i, item in enumerate(res):
f.write(test_data_map["test"][i]["name"])
for dist in item:
f.write(SEP)
f.write(str(1 / dist))
f.write("\n")
type=int,
help='Number of iteration times.')
parser.add_argument('-prew2v',
default=True,
type=bool,
help='If use pre-trained word2vec.')
parser.add_argument('-loss_fn',
default='margin_loss_v1',
type=str,
help='loss functions.')
parser.add_argument('-dataname',
default='aapd',
type=str,
help='Name of dataset.')
parser.add_argument('-bestpath',
default=r'./data/saved/best/best_model.ckpt',
type=str,
help='File Path of the best models.')
cfg = parser.parse_args()
if __name__ == "__main__":
# print(cfg.gpus[0])
model = Model(cfg)
# model.BuildArch()
model.train()
def __init__(self):
# AbstractWidget.__init__(self)
Model.__init__(self, self.__defaults())
