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main_task_free.py
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main_task_free.py
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#!/usr/bin/env python3
import os
import numpy as np
import time
import torch
from torch import optim
# -custom-written libraries
import utils
from utils import checkattr
from data.load import get_context_set
from data.labelstream import SharpBoundaryStream, RandomStream, FuzzyBoundaryStream
from data.datastream import DataStream
from models import define_models as define
from models.cl.continual_learner import ContinualLearner
from models.cl.memory_buffer_stream import MemoryBuffer
from train.train_stream import train_on_stream, train_gen_classifier_on_stream
from params import options
from params.param_stamp import get_param_stamp, get_param_stamp_from_args, visdom_name
from params.param_values import set_method_options,check_for_errors,set_default_values
from eval import evaluate, callbacks as cb
## Function for specifying input-options and organizing / checking them
def handle_inputs():
# Set indicator-dictionary for correctly retrieving / checking input options
kwargs = {'main': True, 'no_boundaries': True}
# Define input options
parser = options.define_args(filename="main_task_free",
description='Run a "task-free" continual learning experiment '
'(i.e., no [known,] sharp boundaries between contexts).')
parser = options.add_general_options(parser, **kwargs)
parser = options.add_eval_options(parser, **kwargs)
parser = options.add_problem_options(parser, **kwargs)
parser = options.add_model_options(parser, **kwargs)
parser = options.add_train_options(parser, **kwargs)
parser = options.add_cl_options(parser, **kwargs)
# Parse, process and check chosen options
args = parser.parse_args()
set_method_options(args) # -"convenience"-option used, select components
set_default_values(args, also_hyper_params=True, no_boundaries=True) # -set defaults, some based on chosen options
check_for_errors(args, **kwargs) # -check for incompatible options
return args
def run(args, verbose=False):
# Create plots- and results-directories if needed
if not os.path.isdir(args.r_dir):
os.mkdir(args.r_dir)
if checkattr(args, 'pdf') and not os.path.isdir(args.p_dir):
os.mkdir(args.p_dir)
# If only want param-stamp, get it printed to screen and exit
if checkattr(args, 'get_stamp'):
print(get_param_stamp_from_args(args=args, no_boundaries=True))
exit()
# Use cuda?
cuda = torch.cuda.is_available() and args.cuda
device = torch.device("cuda" if cuda else "cpu")
# Report whether cuda is used
if verbose:
print("CUDA is {}used".format("" if cuda else "NOT(!!) "))
# Set random seeds
np.random.seed(args.seed)
torch.manual_seed(args.seed)
if cuda:
torch.cuda.manual_seed(args.seed)
#-------------------------------------------------------------------------------------------------#
#-----------------------#
#----- CONTEXT SET -----#
#-----------------------#
# Prepare the context set for the chosen experiment
if verbose:
print("\n\n " +' LOAD DATA '.center(70, '*'))
(train_datasets, test_datasets), config = get_context_set(
name=args.experiment, scenario=args.scenario, contexts=args.contexts, data_dir=args.d_dir,
normalize=checkattr(args, "normalize"), verbose=verbose, exception=(args.seed==0),
singlehead=checkattr(args, 'singlehead')
)
#-------------------------------------------------------------------------------------------------#
#-----------------------------#
#----- FEATURE EXTRACTOR -----#
#-----------------------------#
# Define the feature extractor
depth = args.depth if hasattr(args, 'depth') else 0
use_feature_extractor = checkattr(args, 'hidden') or (
checkattr(args, 'freeze_convE') and (not args.replay=="generative") and (not checkattr(args, "add_buffer"))
and (not checkattr(args, 'gen_classifier'))
)
#--> when the convolutional layers are frozen, it is faster to put the data through these layers only once at the
# beginning, but this currently does not work with iCaRL or pixel-level generative replay/classification
if use_feature_extractor and depth>0:
if verbose:
print("\n\n " + ' DEFINE FEATURE EXTRACTOR '.center(70, '*'))
feature_extractor = define.define_feature_extractor(args=args, config=config, device=device)
# - initialize (pre-trained) parameters
define.init_params(feature_extractor, args, verbose=verbose)
# - freeze the parameters & set model to eval()-mode
for param in feature_extractor.parameters():
param.requires_grad = False
feature_extractor.eval()
# - print characteristics of feature extractor on the screen
if verbose:
utils.print_model_info(feature_extractor)
# - reset size and # of channels to reflect the extracted features rather than the original images
config = config.copy() # -> make a copy to avoid overwriting info in the original config-file
config['size'] = feature_extractor.conv_out_size
config['channels'] = feature_extractor.conv_out_channels
depth = 0
else:
feature_extractor = None
# Convert original data to features (so this doesn't need to be done at run-time)
if (feature_extractor is not None) and args.depth>0:
if verbose:
print("\n\n " + ' PUT DATA TRHOUGH FEATURE EXTRACTOR '.center(70, '*'))
train_datasets = utils.preprocess(feature_extractor, train_datasets, config, batch=args.batch,
message='<TRAINSET>')
test_datasets = utils.preprocess(feature_extractor, test_datasets, config, batch=args.batch,
message='<TESTSET> ')
#-------------------------------------------------------------------------------------------------#
#-----------------------#
#----- DATA-STREAM -----#
#-----------------------#
# Set up the stream of context-labels to use
if args.stream == "academic-setting":
label_stream = SharpBoundaryStream(n_contexts=args.contexts, iters_per_context=args.iters)
elif args.stream == "fuzzy-boundaries":
label_stream = FuzzyBoundaryStream(
n_contexts=args.contexts, iters_per_context=args.iters, fuzziness=args.fuzziness,
batch_size=1 if checkattr(args, 'labels_per_batch') else args.batch
)
elif args.stream == "random":
label_stream = RandomStream(n_contexts=args.contexts)
else:
raise NotImplementedError("Stream type '{}' not currently implemented.".format(args.stream))
# Set up the data-stream to be presented to the network
data_stream = DataStream(
train_datasets, label_stream, batch_size=args.batch, return_context=(args.scenario=="task"),
per_batch=True if (args.stream=="academic-setting") else checkattr(args, 'labels_per_batch'),
)
#-------------------------------------------------------------------------------------------------#
#----------------------#
#----- CLASSIFIER -----#
#----------------------#
# Define the classifier
if verbose:
print("\n\n " + ' DEFINE THE CLASSIFIER '.center(70, '*'))
model = define.define_classifier(args=args, config=config, device=device, depth=depth, stream=True)
# Some type of classifiers consist of multiple networks
n_networks = len(train_datasets) if checkattr(args, 'separate_networks') else (
model.classes if checkattr(args, 'gen_classifier') else 1
)
# Go through all networks to ...
for network_id in range(n_networks):
model_to_set = getattr(model, 'context{}'.format(network_id+1)) if checkattr(args, 'separate_networks') else (
getattr(model, 'vae{}'.format(network_id)) if checkattr(args, 'gen_classifier') else model
)
# ... initialize / use pre-trained / freeze model-parameters, and
define.init_params(model_to_set, args)
# ... define optimizer (only include parameters that "requires_grad")
model_to_set.optim_list = [{'params': filter(lambda p: p.requires_grad, model_to_set.parameters()),
'lr': args.lr}]
model_to_set.optim_type = args.optimizer
if model_to_set.optim_type=="adam":
model_to_set.optimizer = optim.Adam(model_to_set.optim_list, betas=(0.9, 0.999))
elif model_to_set.optim_type=="sgd":
model_to_set.optimizer = optim.SGD(model_to_set.optim_list,
momentum=args.momentum if hasattr(args, 'momentum') else 0.)
# On what scenario will model be trained?
model.scenario = args.scenario
model.classes_per_context = config['classes_per_context']
# Print some model-characteristics on the screen
if verbose:
if checkattr(args, 'gen_classifier') or checkattr(args, 'separate_networks'):
message = '{} copies of:'.format(len(train_datasets))
utils.print_model_info(model.vae0 if checkattr(args, 'gen_classifier') else model.context1, message=message)
else:
utils.print_model_info(model)
# -------------------------------------------------------------------------------------------------#
# For multiple continual learning methods: how often (after how many iters) to perform the consolidation operation?
# (this can be interpreted as: how many iterations together should be considered a "context")
model.update_every = args.update_every if hasattr(args, 'update_every') else 1
# -------------------------------------------------------------------------------------------------#
# ----------------------------------------------------#
# ----- CL-STRATEGY: CONTEXT-SPECIFIC COMPONENTS -----#
# ----------------------------------------------------#
# XdG: already indicated when defining the classifier
#-------------------------------------------------------------------------------------------------#
#-------------------------------------------------#
#----- CL-STRATEGY: PARAMETER REGULARIZATION -----#
#-------------------------------------------------#
# Parameter regularization by adding a weight penalty (e.g., SI)
if isinstance(model, ContinualLearner) and checkattr(args, 'weight_penalty'):
model.weight_penalty = True
model.importance_weighting = args.importance_weighting
model.reg_strength = args.reg_strength
if model.importance_weighting=='si':
model.epsilon = args.epsilon if hasattr(args, 'epsilon') else 0.1
#-------------------------------------------------------------------------------------------------#
#--------------------------------------------------#
#----- CL-STRATEGY: FUNCTIONAL REGULARIZATION -----#
#--------------------------------------------------#
# Should a distillation loss (i.e., soft targets) be used? (e.g., for LwF)
if isinstance(model, ContinualLearner) and hasattr(args, 'replay'):
model.replay_targets = "soft" if checkattr(args, 'distill') else "hard"
model.KD_temp = args.temp if hasattr(args, 'temp') else 2.
#-------------------------------------------------------------------------------------------------#
#-------------------------------#
#----- CL-STRATEGY: REPLAY -----#
#-------------------------------#
# Should the model be trained with replay?
if isinstance(model, ContinualLearner) and hasattr(args, 'replay'):
model.replay_mode = args.replay
# A-GEM: How should the gradient of the loss on replayed data be used? (added, as inequality constraint or both?)
if isinstance(model, ContinualLearner) and hasattr(args, 'use_replay'):
model.use_replay = args.use_replay
model.eps_agem = args.eps_agem if hasattr(args, 'eps_agem') else 0.
#-------------------------------------------------------------------------------------------------#
#-------------------------#
#----- MEMORY BUFFER -----#
#-------------------------#
# Should a memory buffer be maintained? (e.g., for experience replay or prototype-based classification)
use_memory_buffer = checkattr(args, 'prototypes') or args.replay=="buffer"
if isinstance(model, MemoryBuffer) and use_memory_buffer:
model.use_memory_buffer = True
model.budget = args.budget
model.initialize_buffer(config, return_c=(args.scenario=='task'))
# Should classification be done using prototypes as class templates?
model.prototypes = checkattr(args, 'prototypes')
# Relevant for "modified iCaRL": whether to use binary loss
if model.label=="Classifier":
model.binaryCE = checkattr(args, 'bce')
#-------------------------------------------------------------------------------------------------#
#---------------------------#
#----- PARAMETER STAMP -----#
#---------------------------#
# Get parameter-stamp (and print on screen)
if verbose:
if verbose:
print('\n\n' + ' PARAMETER STAMP '.center(70, '*'))
param_stamp = get_param_stamp(
args, model.name, feature_extractor_name= feature_extractor.name if (feature_extractor is not None) else None,
verbose=verbose, no_boundaries=True,
)
#-------------------------------------------------------------------------------------------------#
#---------------------#
#----- CALLBACKS -----#
#---------------------#
# Setting up Visdom environment
if utils.checkattr(args, 'visdom'):
if verbose:
print('\n\n'+' VISDOM '.center(70, '*'))
from visdom import Visdom
env_name = "{exp}{con}-{sce}".format(exp=args.experiment, con=args.contexts, sce=args.scenario)
visdom = {'env': Visdom(env=env_name), 'graph': visdom_name(args)}
else:
visdom = None
# Callbacks for reporting and visualizing loss
loss_cbs = [
cb._gen_classifier_loss_cb(
log=args.loss_log, classes=None, visdom=None,
) if checkattr(args, 'gen_classifier') else cb._classifier_loss_cb(
log=args.loss_log, visdom=visdom, model=model, contexts=None,
)
]
# Callbacks for reporting and visualizing accuracy
eval_cbs = [
cb._eval_cb(log=args.acc_log, test_datasets=test_datasets, visdom=visdom, iters_per_context=args.iters,
test_size=args.acc_n)
]
#-------------------------------------------------------------------------------------------------#
#--------------------#
#----- TRAINING -----#
#--------------------#
# Train model
if args.train:
if verbose:
print('\n\n' + ' TRAINING '.center(70, '*'))
# -keep track of training-time
if args.time:
start = time.time()
# -select training function
train_fn = train_gen_classifier_on_stream if checkattr(args, 'gen_classifier') else train_on_stream
# -perform training
train_fn(model, data_stream, iters=args.iters*args.contexts, eval_cbs=eval_cbs, loss_cbs=loss_cbs)
# -get total training-time in seconds, write to file and print to screen
if args.time:
training_time = time.time() - start
time_file = open("{}/time-{}.txt".format(args.r_dir, param_stamp), 'w')
time_file.write('{}\n'.format(training_time))
time_file.close()
if verbose and args.time:
print("Total training time = {:.1f} seconds\n".format(training_time))
# -save trained model(s), if requested
if args.save:
save_name = "mM-{}".format(param_stamp) if (
not hasattr(args, 'full_stag') or args.full_stag == "none"
) else "{}-{}".format(model.name, args.full_stag)
utils.save_checkpoint(model, args.m_dir, name=save_name, verbose=verbose)
else:
# Load previously trained model(s) (if goal is to only evaluate previously trained model)
if verbose:
print("\nLoading parameters of previously trained model...")
load_name = "mM-{}".format(param_stamp) if (
not hasattr(args, 'full_ltag') or args.full_ltag == "none"
) else "{}-{}".format(model.name, args.full_ltag)
utils.load_checkpoint(model, args.m_dir, name=load_name, verbose=verbose, strict=False)
#-------------------------------------------------------------------------------------------------#
#----------------------#
#----- EVALUATION -----#
#----------------------#
if verbose:
print('\n\n' + ' EVALUATION '.center(70, '*'))
# Set attributes of model that define how to do classification
if checkattr(args, 'gen_classifier'):
model.S = args.eval_s
# Evaluate accuracy of final model on full test-set
if verbose:
print("\n Accuracy of final model on test-set:")
accs = []
for context_id in range(args.contexts):
acc = evaluate.test_acc(
model, test_datasets[context_id], verbose=False, context_id=context_id, allowed_classes=list(
range(config['classes_per_context'] * context_id, config['classes_per_context'] * (context_id+1))
) if (args.scenario == "task" and not checkattr(args, 'singlehead')) else None, test_size=None,
)
if verbose:
print(" - Context {}: {:.4f}".format(context_id+1, acc))
accs.append(acc)
average_accs = sum(accs) / args.contexts
if verbose:
print('=> average accuracy over all {} contexts: {:.4f}\n\n'.format(args.contexts, average_accs))
# -write out to text file
file_name = "{}/acc-{}{}.txt".format(args.r_dir, param_stamp,
"--S{}".format(args.eval_s) if checkattr(args, 'gen_classifier') else "")
output_file = open(file_name, 'w')
output_file.write('{}\n'.format(average_accs))
output_file.close()
if __name__ == '__main__':
# -load input-arguments
args = handle_inputs()
# -run experiment
run(args, verbose=True)