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test.py
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test.py
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"""
Evaluation of PolyGNN.
"""
import pickle
from pathlib import Path
import multiprocessing
import numpy as np
import torch
import hydra
from omegaconf import DictConfig
from tqdm import tqdm
from torch.nn.parallel import DistributedDataParallel
from torch_geometric.loader import DataLoader
import torch.multiprocessing as mp
from torchmetrics.classification import BinaryAccuracy
import torch.distributed as dist
from torch_geometric import compile
from network import PolyGNN
from dataset import CityDataset, TestOnlyDataset
from utils import init_device, Sampler, set_seed, attach_to_log, setup_runner
class PredictionSaver:
"""
Asynchronous prediction saving.
"""
def __init__(self, processes):
self.pool = multiprocessing.Pool(processes=processes)
@staticmethod
def save(args):
pred, name, cfg = args
indices_cells = np.where(pred.cpu().numpy())[0]
if len(indices_cells) > 0:
complex_path = f'{cfg.complex_dir}/{name}.cc'
with open(complex_path, 'rb') as handle:
cell_complex = pickle.load(handle)
output_path = f'{cfg.output_dir}/{name}.npy'
output = np.zeros([cell_complex.num_cells], dtype=int)
output[indices_cells] = 1
if cfg.evaluate.seal:
cells_boundary = cell_complex.cells_boundary()
output[cells_boundary] = 0
np.save(output_path, output)
def run_eval(rank, world_size, dataset_test, cfg):
"""
Runner function for distributed inference of PolyGNN.
"""
# set up runner
setup_runner(rank, world_size, cfg.master_addr, cfg.master_port)
# limit number of threads
torch.set_num_threads(cfg.num_workers // world_size)
# initialize logging
logger = attach_to_log(filepath='./outputs/test.log')
# indicate device
logger.debug(f"Device activated: " + f"CUDA: {cfg.gpu_ids[rank]}")
# initialize metric
metric = BinaryAccuracy()
# split test indices into `world_size` many chunks
eval_indices = torch.arange(len(dataset_test))
eval_indices = eval_indices.split(len(eval_indices) // world_size)[rank]
dataloader_test = DataLoader(dataset_test[eval_indices], batch_size=cfg.batch_size // world_size,
shuffle=cfg.shuffle, num_workers=cfg.num_workers // world_size,
pin_memory=True, prefetch_factor=8)
# initialize model
model = PolyGNN(cfg)
model.metric = metric
model = model.to(rank)
# distributed parallelization
model = DistributedDataParallel(model, device_ids=[rank])
# compile model for better performance
compile(model, dynamic=True, fullgraph=True)
# load from checkpoint
map_location = f'cuda:{rank}'
if rank == 0:
logger.info(f'Resuming from {cfg.checkpoint_path}')
state = torch.load(cfg.checkpoint_path, map_location=map_location)
state_dict = state['state_dict']
model.load_state_dict(state_dict, strict=False)
# specify data attributes
if cfg.sample.strategy == 'grid':
points_suffix = f'_{cfg.sample.resolution}'
elif cfg.sample.strategy == 'random':
points_suffix = f'_{cfg.sample.length}'
else:
points_suffix = ''
# start inference
model.eval()
pbar = tqdm(dataloader_test, desc=f'eval', disable=rank != 0)
# initialize PredictionSaver instance
prediction_saver = PredictionSaver(processes=cfg.num_workers // world_size)
with torch.no_grad():
for batch in pbar:
batch = batch.to(rank, f'points{points_suffix}', f'batch_points{points_suffix}', 'queries',
'edge_index', 'batch', 'y')
outs = model(batch)
outs = outs.argmax(dim=1)
targets = batch.y
# metric on current batch
_accuracy = metric(outs, targets)
pbar.set_postfix_str('acc={:.2f}'.format(_accuracy))
# save prediction as numpy file
if cfg.evaluate.save:
Path(cfg.output_dir).mkdir(exist_ok=True)
_, boundary_indices = torch.unique(batch.batch, return_counts=True)
preds = torch.split(outs, split_size_or_sections=boundary_indices.tolist(), dim=0)
names = batch.name
# asynchronous file saving
prediction_saver.pool.map(prediction_saver.save, zip(preds, names, [cfg] * len(preds)))
# metric on all batches and all accelerators using custom accumulation
accuracy = metric.compute()
if rank == 0:
logger.info(f"Evaluation accuracy: {accuracy}")
# reset internal state such that metric ready for new data
metric.reset()
dist.barrier()
dist.destroy_process_group()
@hydra.main(config_path='./conf', config_name='config', version_base='1.2')
def test(cfg: DictConfig):
"""
Test PolyGNN for reconstruction.
Parameters
----------
cfg: DictConfig
Hydra configuration
"""
# initialize logger
logger = attach_to_log(filepath='./outputs/test.log')
# initialize device
init_device(cfg.gpu_ids, register_freeze=cfg.gpu_freeze)
logger.info(f"Device initialized: " + f"CUDA: {cfg.gpu_ids}")
# fix randomness
set_seed(cfg.seed)
logger.info(f"Random seed set to {cfg.seed}")
# initialize data sampler
sampler = Sampler(strategy=cfg.sample.strategy, length=cfg.sample.length, ratio=cfg.sample.ratio,
resolutions=cfg.sample.resolutions, duplicate=cfg.sample.duplicate, seed=cfg.seed)
transform = sampler.sample if cfg.sample.transform else None
pre_transform = sampler.sample if cfg.sample.pre_transform else None
# initialize dataset
if cfg.dataset in {'munich', 'munich_perturb', 'munich_subsample', 'munich_truncate', 'munich_haswall', 'campus_ldbv'}:
dataset = TestOnlyDataset(pre_transform=pre_transform, transform=transform, root=cfg.data_dir,
split='test', num_workers=cfg.num_workers)
else:
dataset = CityDataset(pre_transform=pre_transform, transform=transform, root=cfg.data_dir,
split='test', num_workers=cfg.num_workers)
world_size = len(cfg.gpu_ids)
mp.spawn(run_eval, args=(world_size, dataset, cfg), nprocs=world_size, join=True)
if __name__ == '__main__':
test()