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eval_conditional_qm9.py
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eval_conditional_qm9.py
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import argparse
from os.path import join
import torch
import pickle
from qm9.models import get_model
from configs.datasets_config import get_dataset_info
from qm9 import dataset
from qm9.utils import compute_mean_mad
from qm9.sampling import sample
from qm9.property_prediction.main_qm9_prop import test
from qm9.property_prediction import main_qm9_prop
from qm9.sampling import sample_chain, sample, sample_sweep_conditional
import qm9.visualizer as vis
def get_classifier(dir_path='', device='cpu'):
with open(join(dir_path, 'args.pickle'), 'rb') as f:
args_classifier = pickle.load(f)
args_classifier.device = device
args_classifier.model_name = 'egnn'
classifier = main_qm9_prop.get_model(args_classifier)
classifier_state_dict = torch.load(join(dir_path, 'best_checkpoint.npy'), map_location=torch.device('cpu'))
classifier.load_state_dict(classifier_state_dict)
return classifier
def get_args_gen(dir_path):
with open(join(dir_path, 'args.pickle'), 'rb') as f:
args_gen = pickle.load(f)
assert args_gen.dataset == 'qm9_second_half'
# Add missing args!
if not hasattr(args_gen, 'normalization_factor'):
args_gen.normalization_factor = 1
if not hasattr(args_gen, 'aggregation_method'):
args_gen.aggregation_method = 'sum'
return args_gen
def get_generator(dir_path, dataloaders, device, args_gen, property_norms):
dataset_info = get_dataset_info(args_gen.dataset, args_gen.remove_h)
model, nodes_dist, prop_dist = get_model(args_gen, device, dataset_info, dataloaders['train'])
fn = 'generative_model_ema.npy' if args_gen.ema_decay > 0 else 'generative_model.npy'
model_state_dict = torch.load(join(dir_path, fn), map_location='cpu')
model.load_state_dict(model_state_dict)
# The following function be computes the normalization parameters using the 'valid' partition
if prop_dist is not None:
prop_dist.set_normalizer(property_norms)
return model.to(device), nodes_dist, prop_dist, dataset_info
def get_dataloader(args_gen):
dataloaders, charge_scale = dataset.retrieve_dataloaders(args_gen)
return dataloaders
class DiffusionDataloader:
def __init__(self, args_gen, model, nodes_dist, prop_dist, device, unkown_labels=False,
batch_size=1, iterations=200):
self.args_gen = args_gen
self.model = model
self.nodes_dist = nodes_dist
self.prop_dist = prop_dist
self.batch_size = batch_size
self.iterations = iterations
self.device = device
self.unkown_labels = unkown_labels
self.dataset_info = get_dataset_info(self.args_gen.dataset, self.args_gen.remove_h)
self.i = 0
def __iter__(self):
return self
def sample(self):
nodesxsample = self.nodes_dist.sample(self.batch_size)
context = self.prop_dist.sample_batch(nodesxsample).to(self.device)
one_hot, charges, x, node_mask = sample(self.args_gen, self.device, self.model,
self.dataset_info, self.prop_dist, nodesxsample=nodesxsample,
context=context)
node_mask = node_mask.squeeze(2)
context = context.squeeze(1)
# edge_mask
bs, n_nodes = node_mask.size()
edge_mask = node_mask.unsqueeze(1) * node_mask.unsqueeze(2)
diag_mask = ~torch.eye(edge_mask.size(1), dtype=torch.bool).unsqueeze(0)
diag_mask = diag_mask.to(self.device)
edge_mask *= diag_mask
edge_mask = edge_mask.view(bs * n_nodes * n_nodes, 1)
prop_key = self.prop_dist.properties[0]
if self.unkown_labels:
context[:] = self.prop_dist.normalizer[prop_key]['mean']
else:
context = context * self.prop_dist.normalizer[prop_key]['mad'] + self.prop_dist.normalizer[prop_key]['mean']
data = {
'positions': x.detach(),
'atom_mask': node_mask.detach(),
'edge_mask': edge_mask.detach(),
'one_hot': one_hot.detach(),
prop_key: context.detach()
}
return data
def __next__(self):
if self.i <= self.iterations:
self.i += 1
return self.sample()
else:
self.i = 0
raise StopIteration
def __len__(self):
return self.iterations
def main_quantitative(args):
# Get classifier
#if args.task == "numnodes":
# class_dir = args.classifiers_path[:-6] + "numnodes_%s" % args.property
#else:
class_dir = args.classifiers_path
classifier = get_classifier(class_dir).to(args.device)
# Get generator and dataloader used to train the generator and evalute the classifier
args_gen = get_args_gen(args.generators_path)
# Careful with this -->
if not hasattr(args_gen, 'diffusion_noise_precision'):
args_gen.normalization_factor = 1e-4
if not hasattr(args_gen, 'normalization_factor'):
args_gen.normalization_factor = 1
if not hasattr(args_gen, 'aggregation_method'):
args_gen.aggregation_method = 'sum'
dataloaders = get_dataloader(args_gen)
property_norms = compute_mean_mad(dataloaders, args_gen.conditioning, args_gen.dataset)
model, nodes_dist, prop_dist, _ = get_generator(args.generators_path, dataloaders,
args.device, args_gen, property_norms)
# Create a dataloader with the generator
mean, mad = property_norms[args.property]['mean'], property_norms[args.property]['mad']
if args.task == 'edm':
diffusion_dataloader = DiffusionDataloader(args_gen, model, nodes_dist, prop_dist,
args.device, batch_size=args.batch_size, iterations=args.iterations)
print("EDM: We evaluate the classifier on our generated samples")
loss = test(classifier, 0, diffusion_dataloader, mean, mad, args.property, args.device, 1, args.debug_break)
print("Loss classifier on Generated samples: %.4f" % loss)
elif args.task == 'qm9_second_half':
print("qm9_second_half: We evaluate the classifier on QM9")
loss = test(classifier, 0, dataloaders['train'], mean, mad, args.property, args.device, args.log_interval,
args.debug_break)
print("Loss classifier on qm9_second_half: %.4f" % loss)
elif args.task == 'naive':
print("Naive: We evaluate the classifier on QM9")
length = dataloaders['train'].dataset.data[args.property].size(0)
idxs = torch.randperm(length)
dataloaders['train'].dataset.data[args.property] = dataloaders['train'].dataset.data[args.property][idxs]
loss = test(classifier, 0, dataloaders['train'], mean, mad, args.property, args.device, args.log_interval,
args.debug_break)
print("Loss classifier on naive: %.4f" % loss)
#elif args.task == 'numnodes':
# print("Numnodes: We evaluate the numnodes classifier on EDM samples")
# diffusion_dataloader = DiffusionDataloader(args_gen, model, nodes_dist, prop_dist, device,
# batch_size=args.batch_size, iterations=args.iterations)
# loss = test(classifier, 0, diffusion_dataloader, mean, mad, args.property, args.device, 1, args.debug_break)
# print("Loss numnodes classifier on EDM generated samples: %.4f" % loss)
def save_and_sample_conditional(args, device, model, prop_dist, dataset_info, epoch=0, id_from=0):
one_hot, charges, x, node_mask = sample_sweep_conditional(args, device, model, dataset_info, prop_dist)
vis.save_xyz_file(
'outputs/%s/analysis/run%s/' % (args.exp_name, epoch), one_hot, charges, x, dataset_info,
id_from, name='conditional', node_mask=node_mask)
vis.visualize_chain("outputs/%s/analysis/run%s/" % (args.exp_name, epoch), dataset_info,
wandb=None, mode='conditional', spheres_3d=True)
return one_hot, charges, x
def main_qualitative(args):
args_gen = get_args_gen(args.generators_path)
dataloaders = get_dataloader(args_gen)
property_norms = compute_mean_mad(dataloaders, args_gen.conditioning, args_gen.dataset)
model, nodes_dist, prop_dist, dataset_info = get_generator(args.generators_path,
dataloaders, args.device, args_gen,
property_norms)
for i in range(args.n_sweeps):
print("Sampling sweep %d/%d" % (i+1, args.n_sweeps))
save_and_sample_conditional(args_gen, device, model, prop_dist, dataset_info, epoch=i, id_from=0)
if __name__ == "__main__":
parser = argparse.ArgumentParser()
parser.add_argument('--exp_name', type=str, default='debug_alpha')
parser.add_argument('--generators_path', type=str, default='outputs/exp_cond_alpha_pretrained')
parser.add_argument('--classifiers_path', type=str, default='qm9/property_prediction/outputs/exp_class_alpha_pretrained')
parser.add_argument('--property', type=str, default='alpha',
help="'alpha', 'homo', 'lumo', 'gap', 'mu', 'Cv'")
parser.add_argument('--no-cuda', action='store_true', default=False,
help='enables CUDA training')
parser.add_argument('--debug_break', type=eval, default=False,
help='break point or not')
parser.add_argument('--log_interval', type=int, default=5,
help='break point or not')
parser.add_argument('--batch_size', type=int, default=1,
help='break point or not')
parser.add_argument('--iterations', type=int, default=20,
help='break point or not')
parser.add_argument('--task', type=str, default='qualitative',
help='naive, edm, qm9_second_half, qualitative')
parser.add_argument('--n_sweeps', type=int, default=10,
help='number of sweeps for the qualitative conditional experiment')
args = parser.parse_args()
args.cuda = not args.no_cuda and torch.cuda.is_available()
device = torch.device("cuda" if args.cuda else "cpu")
args.device = device
if args.task == 'qualitative':
main_qualitative(args)
else:
main_quantitative(args)