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PyCIL_Stanford_Car

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	import sys
	import logging
	import copy
	import torch
	from utils import factory
	from utils.data_manager import DataManager
	from utils.toolkit import count_parameters
	import os
	import numpy as np


	def train(args):
	seed_list = copy.deepcopy(args["seed"])
	device = copy.deepcopy(args["device"])

	for seed in seed_list:
	args["seed"] = seed
	args["device"] = device
	_train(args)


	def _train(args):

	init_cls = 0 if args ["init_cls"] == args["increment"] else args["init_cls"]
	logs_name = "logs/{}/{}_{}/{}/{}".format(args["model_name"],args["dataset"], args['data'], init_cls, args['increment'])

	if not os.path.exists(logs_name):
	os.makedirs(logs_name)

	save_name = "models/{}/{}_{}/{}/{}".format(args["model_name"],args["dataset"], args['data'], init_cls, args['increment'])

	if not os.path.exists(save_name):
	os.makedirs(save_name)
	if not os.path.exists(logs_name):
	os.makedirs(logs_name)
	logfilename = "logs/{}/{}_{}/{}/{}/{}_{}_{}".format(
	args["model_name"],
	args["dataset"],
	args['data'],
	init_cls,
	args["increment"],
	args["prefix"],
	args["seed"],
	args["convnet_type"],
	)
	logging.basicConfig(
	level=logging.INFO,
	format="%(asctime)s [%(filename)s] => %(message)s",
	handlers=[
	logging.FileHandler(filename=logfilename + ".log"),
	logging.StreamHandler(sys.stdout),
	],
	force=True
	)
	args['logfilename'] = logs_name
	args['csv_name'] = "{}_{}_{}".format(
	args["prefix"],
	args["seed"],
	args["convnet_type"],
	)


	_set_random()
	_set_device(args)
	print_args(args)
	model = factory.get_model(args["model_name"], args)
	data_manager = DataManager(
	args["dataset"],
	args["shuffle"],
	args["seed"],
	args["init_cls"],
	args["increment"],
	path = args["data"],
	)

	cnn_curve, nme_curve = {"top1": [], "top5": []}, {"top1": [], "top5": []}
	cnn_matrix, nme_matrix = [], []

	for task in range(data_manager.nb_tasks):
	print(args["device"])
	logging.info("All params: {}".format(count_parameters(model._network)))
	logging.info(
	"Trainable params: {}".format(count_parameters(model._network, True))
	)
	model.incremental_train(data_manager)
	cnn_accy, nme_accy = model.eval_task(save_conf=True)
	model.after_task()

	if nme_accy is not None:
	logging.info("CNN: {}".format(cnn_accy["grouped"]))
	logging.info("NME: {}".format(nme_accy["grouped"]))

	cnn_keys = [key for key in cnn_accy["grouped"].keys() if '-' in key]
	cnn_keys_sorted = sorted(cnn_keys)
	cnn_values = [cnn_accy["grouped"][key] for key in cnn_keys_sorted]
	cnn_matrix.append(cnn_values)

	nme_keys = [key for key in nme_accy["grouped"].keys() if '-' in key]
	nme_keys_sorted = sorted(nme_keys)
	nme_values = [nme_accy["grouped"][key] for key in nme_keys_sorted]
	nme_matrix.append(nme_values)


	cnn_curve["top1"].append(cnn_accy["top1"])
	cnn_curve["top5"].append(cnn_accy["top5"])

	nme_curve["top1"].append(nme_accy["top1"])
	nme_curve["top5"].append(nme_accy["top5"])

	logging.info("CNN top1 curve: {}".format(cnn_curve["top1"]))
	logging.info("CNN top5 curve: {}".format(cnn_curve["top5"]))
	logging.info("NME top1 curve: {}".format(nme_curve["top1"]))
	logging.info("NME top5 curve: {}\n".format(nme_curve["top5"]))

	print('Average Accuracy (CNN):', sum(cnn_curve["top1"])/len(cnn_curve["top1"]))
	print('Average Accuracy (NME):', sum(nme_curve["top1"])/len(nme_curve["top1"]))

	logging.info("Average Accuracy (CNN): {}".format(sum(cnn_curve["top1"])/len(cnn_curve["top1"])))
	logging.info("Average Accuracy (NME): {}".format(sum(nme_curve["top1"])/len(nme_curve["top1"])))
	else:
	logging.info("No NME accuracy.")
	logging.info("CNN: {}".format(cnn_accy["grouped"]))

	cnn_keys = [key for key in cnn_accy["grouped"].keys() if '-' in key]
	cnn_keys_sorted = sorted(cnn_keys)
	cnn_values = [cnn_accy["grouped"][key] for key in cnn_keys_sorted]
	cnn_matrix.append(cnn_values)

	cnn_curve["top1"].append(cnn_accy["top1"])
	cnn_curve["top5"].append(cnn_accy["top5"])

	logging.info("CNN top1 curve: {}".format(cnn_curve["top1"]))
	logging.info("CNN top5 curve: {}\n".format(cnn_curve["top5"]))

	print('Average Accuracy (CNN):', sum(cnn_curve["top1"])/len(cnn_curve["top1"]))
	logging.info("Average Accuracy (CNN): {}".format(sum(cnn_curve["top1"])/len(cnn_curve["top1"])))
	model.save_checkpoint(save_name)
	if len(cnn_matrix)>0:
	np_acctable = np.zeros([ task + 1, int((args["init_cls"] // 10) + task * (args["increment"] // 10))])
	for idxx, line in enumerate(cnn_matrix):
	idxy = len(line)
	np_acctable[idxx, :idxy] = np.array(line)
	np_acctable = np_acctable.T
	forgetting = np.mean((np.max(np_acctable, axis=1) - np_acctable[:, -1])[:-1])
	logging.info('Forgetting (CNN): {}'.format(forgetting))
	logging.info('Accuracy Matrix (CNN): {}'.format(np_acctable))
	print('Accuracy Matrix (CNN):')
	print(np_acctable)
	print('Forgetting (CNN):', forgetting)
	if len(nme_matrix)>0:
	np_acctable = np.zeros([ task + 1, int((args["init_cls"] // 10) + task * (args["increment"] // 10))])
	for idxx, line in enumerate(nme_matrix):
	idxy = len(line)
	np_acctable[idxx, :idxy] = np.array(line)
	np_acctable = np_acctable.T
	forgetting = np.mean((np.max(np_acctable, axis=1) - np_acctable[:, -1])[:-1])
	logging.info('Forgetting (NME): {}'.format(forgetting))
	logging.info('Accuracy Matrix (NME): {}'.format(np_acctable))
	print('Accuracy Matrix (NME):')
	print(np_acctable)
	print('Forgetting (NME):', forgetting)

	def _set_device(args):
	device_type = args["device"]
	gpus = []

	for device in device_type:
	if device == -1:
	device = torch.device("cpu")
	else:
	device = torch.device("cuda:{}".format(device))

	gpus.append(device)

	args["device"] = gpus


	def _set_random():
	torch.manual_seed(1)
	torch.cuda.manual_seed(1)
	torch.cuda.manual_seed_all(1)
	torch.backends.cudnn.deterministic = True
	torch.backends.cudnn.benchmark = False


	def print_args(args):
	for key, value in args.items():
	logging.info("{}: {}".format(key, value))