def _run(model, data, opt, log):
epochs = range(opt.epochs)
lr_base = ops.convert_to_tensor(opt.lr,
name="learning_rate",
dtype=tf.float64)
for epoch in epochs:
data.burnin = opt.burnin > 0 and epoch < opt.burnin
lr_mult = (tf.constant(opt.burnin_multiplier, dtype=tf.float64)
if data.burnin else tf.constant(1, dtype=tf.float64))
lr = lr_base * lr_mult
e_losses = tf.constant([], dtype=tf.float64)
for batch, (inputs, outputs) in enumerate(data):
cur_loss = train(model, inputs, outputs, learning_rate=lr)
if cur_loss is not None:
e_losses = tf.concat([e_losses, [cur_loss]], axis=0)
if epoch % opt.eval_each == 0:
log.info(
f"epoch {epoch} - loss: {tf.reduce_mean(e_losses)}, lr: {lr}]")
model.save_weights(opt.checkpoint) # TODO - use model.save()
def main():
parser = argparse.ArgumentParser(description='Train Hyperbolic Embeddings')
parser.add_argument('-dset', type=str, required=True,
help='Dataset identifier')
parser.add_argument('-dim', type=int, default=20,
help='Embedding dimension')
parser.add_argument('-com_n', type=int, default=2,
help='Embedding components number')
parser.add_argument('-manifold', type=str, default='lorentz',
choices=MANIFOLDS.keys(), help='Embedding manifold')
parser.add_argument('-lr', type=float, default=1000,
help='Learning rate')
parser.add_argument('-epochs', type=int, default=100,
help='Number of epochs')
parser.add_argument('-batchsize', type=int, default=12800,
help='Batchsize')
parser.add_argument('-negs', type=int, default=50,
help='Number of negatives')
parser.add_argument('-burnin', type=int, default=20,
help='Epochs of burn in')
parser.add_argument('-dampening', type=float, default=0.75,
help='Sample dampening during burnin')
parser.add_argument('-ndproc', type=int, default=8,
help='Number of data loading processes')
parser.add_argument('-eval_each', type=int, default=1,
help='Run evaluation every n-th epoch')
parser.add_argument('-debug', action='store_true', default=False,
help='Print debuggin output')
parser.add_argument('-gpu', default=-1, type=int,
help='Which GPU to run on (-1 for no gpu)')
parser.add_argument('-sym', action='store_true', default=False,
help='Symmetrize dataset')
parser.add_argument('-maxnorm', '-no-maxnorm', default='500000',
action=Unsettable, type=int)
parser.add_argument('-sparse', default=False, action='store_true',
help='Use sparse gradients for embedding table')
parser.add_argument('-burnin_multiplier', default=0.01, type=float)
parser.add_argument('-neg_multiplier', default=1.0, type=float)
parser.add_argument('-quiet', action='store_true', default=True)
parser.add_argument('-lr_type', choices=['scale', 'constant'], default='constant')
parser.add_argument('-train_threads', type=int, default=1,
help='Number of threads to use in training')
parser.add_argument('-eval_embedding', default=False, help='path for the embedding to be evaluated')
opt = parser.parse_args()
if 'LTiling' in opt.manifold:
opt.nor = 'LTiling'
opt.norevery = 20
opt.stre = 50
elif 'HTiling' in opt.manifold:
opt.nor = 'HTiling'
opt.norevery = 1
opt.stre = 0
else:
opt.nor = 'none'
# setup debugging and logigng
log_level = logging.DEBUG if opt.debug else logging.INFO
log = logging.getLogger('tiling model')
logging.basicConfig(level=log_level, format='%(message)s', stream=sys.stdout)
# set default tensor type
th.set_default_tensor_type('torch.DoubleTensor')####FloatTensor DoubleTensor
# set device
# device = th.device(f'cuda:{opt.gpu}' if opt.gpu >= 0 else 'cpu')
device = th.device('cpu')
# select manifold to optimize on
manifold = MANIFOLDS[opt.manifold](debug=opt.debug, max_norm=opt.maxnorm, com_n=opt.com_n)
if 'Halfspace' not in opt.manifold:
opt.dim = manifold.dim(opt.dim)
if 'csv' in opt.dset:
log.info('Using edge list dataloader')
idx, objects, weights = load_edge_list(opt.dset, opt.sym)
model, data, model_name, conf = initialize(
manifold, opt, idx, objects, weights, sparse=opt.sparse
)
else:
log.info('Using adjacency matrix dataloader')
dset = load_adjacency_matrix(opt.dset, 'hdf5')
log.info('Setting up dataset...')
data = AdjacencyDataset(dset, opt.negs, opt.batchsize, opt.ndproc,
opt.burnin > 0, sample_dampening=opt.dampening)
model = Embedding(data.N, opt.dim, manifold, sparse=opt.sparse, com_n=opt.com_n)
objects = dset['objects']
print('the total dimension', model.lt.weight.data.size(-1), 'com_n', opt.com_n)
# set burnin parameters
data.neg_multiplier = opt.neg_multiplier
train._lr_multiplier = opt.burnin_multiplier
# Build config string for log
log.info(f'json_conf: {json.dumps(vars(opt))}')
if opt.lr_type == 'scale':
opt.lr = opt.lr * opt.batchsize
# setup optimizer
optimizer = RiemannianSGD(model.optim_params(manifold), lr=opt.lr)
opt.epoch_start = 0
adj = {}
for inputs, _ in data:
for row in inputs:
x = row[0].item()
y = row[1].item()
if x in adj:
adj[x].add(y)
else:
adj[x] = {y}
if not opt.eval_embedding:
opt.adj = adj
model = model.to(device)
if hasattr(model, 'w_avg'):
model.w_avg = model.w_avg.to(device)
if opt.train_threads > 1:
threads = []
model = model.share_memory()
if 'LTiling' in opt.manifold:
model.int_matrix.share_memory_()
kwargs = {'progress' : not opt.quiet}
for i in range(opt.train_threads):
args = (i, device, model, data, optimizer, opt, log)
threads.append(mp.Process(target=train.train, args=args, kwargs=kwargs))
threads[-1].start()
[t.join() for t in threads]
else:
train.train(device, model, data, optimizer, opt, log, progress=not opt.quiet)
else:
model = th.load(opt.eval_embedding, map_location='cpu')['embeddings']
if 'LTiling' in opt.manifold:
meanrank, maprank = eval_reconstruction(adj, model.lt.weight.data.clone(), manifold.distance, lt_int_matrix = model.int_matrix.data.clone(), workers = opt.ndproc)
sqnorms = manifold.pnorm(model.lt.weight.data.clone(), model.int_matrix.data.clone())
else:
meanrank, maprank = eval_reconstruction(adj, model.lt.weight.data.clone(), manifold.distance, workers = opt.ndproc)
sqnorms = manifold.pnorm(model.lt.weight.data.clone())
log.info(
'json_stats final test: {'
f'"sqnorm_min": {sqnorms.min().item()}, '
f'"sqnorm_avg": {sqnorms.mean().item()}, '
f'"sqnorm_max": {sqnorms.max().item()}, '
f'"mean_rank": {meanrank}, '
f'"map": {maprank}, '
'}'
)
print(model.lt.weight.data[0])
def main():
parser = argparse.ArgumentParser(description='Train Hyperbolic Embeddings')
parser.add_argument('-checkpoint', default='/tmp/hype_embeddings.pth',
help='Where to store the model checkpoint')
parser.add_argument('-dset', type=str, required=True,
help='Dataset identifier')
parser.add_argument('-dim', type=int, default=20,
help='Embedding dimension')
parser.add_argument('-manifold', type=str, default='lorentz',
choices=MANIFOLDS.keys(), help='Embedding manifold')
parser.add_argument('-lr', type=float, default=1000,
help='Learning rate')
parser.add_argument('-epochs', type=int, default=100,
help='Number of epochs')
parser.add_argument('-batchsize', type=int, default=12800,
help='Batchsize')
parser.add_argument('-negs', type=int, default=50,
help='Number of negatives')
parser.add_argument('-burnin', type=int, default=20,
help='Epochs of burn in')
parser.add_argument('-dampening', type=float, default=0.75,
help='Sample dampening during burnin')
parser.add_argument('-ndproc', type=int, default=8,
help='Number of data loading processes')
parser.add_argument('-eval_each', type=int, default=1,
help='Run evaluation every n-th epoch')
parser.add_argument('-fresh', action='store_true', default=False,
help='Override checkpoint')
parser.add_argument('-debug', action='store_true', default=False,
help='Print debuggin output')
parser.add_argument('-gpu', default=0, type=int,
help='Which GPU to run on (-1 for no gpu)')
parser.add_argument('-sym', action='store_true', default=False,
help='Symmetrize dataset')
parser.add_argument('-maxnorm', '-no-maxnorm', default='500000',
action=Unsettable, type=int)
parser.add_argument('-sparse', default=False, action='store_true',
help='Use sparse gradients for embedding table')
parser.add_argument('-burnin_multiplier', default=0.01, type=float)
parser.add_argument('-neg_multiplier', default=1.0, type=float)
parser.add_argument('-quiet', action='store_true', default=False)
parser.add_argument('-lr_type', choices=['scale', 'constant'], default='constant')
parser.add_argument('-train_threads', type=int, default=1,
help='Number of threads to use in training')
opt = parser.parse_args()
# setup debugging and logigng
log_level = logging.DEBUG if opt.debug else logging.INFO
log = logging.getLogger('lorentz')
logging.basicConfig(level=log_level, format='%(message)s', stream=sys.stdout)
if opt.gpu >= 0 and opt.train_threads > 1:
opt.gpu = -1
log.warning(f'Specified hogwild training with GPU, defaulting to CPU...')
# set default tensor type
th.set_default_tensor_type('torch.DoubleTensor')
# set device
device = th.device(f'cuda:{opt.gpu}' if opt.gpu >= 0 else 'cpu')
# select manifold to optimize on
manifold = MANIFOLDS[opt.manifold](debug=opt.debug, max_norm=opt.maxnorm)
opt.dim = manifold.dim(opt.dim)
if 'csv' in opt.dset:
log.info('Using edge list dataloader')
idx, objects, weights = load_edge_list(opt.dset, opt.sym)
model, data, model_name, conf = initialize(
manifold, opt, idx, objects, weights, sparse=opt.sparse
)
else:
log.info('Using adjacency matrix dataloader')
dset = load_adjacency_matrix(opt.dset, 'hdf5')
log.info('Setting up dataset...')
data = AdjacencyDataset(dset, opt.negs, opt.batchsize, opt.ndproc,
opt.burnin > 0, sample_dampening=opt.dampening)
model = Embedding(data.N, opt.dim, manifold, sparse=opt.sparse)
objects = dset['objects']
# set burnin parameters
data.neg_multiplier = opt.neg_multiplier
train._lr_multiplier = opt.burnin_multiplier
# Build config string for log
log.info(f'json_conf: {json.dumps(vars(opt))}')
if opt.lr_type == 'scale':
opt.lr = opt.lr * opt.batchsize
# setup optimizer
optimizer = RiemannianSGD(model.optim_params(manifold), lr=opt.lr)
# setup checkpoint
checkpoint = LocalCheckpoint(
opt.checkpoint,
include_in_all={'conf' : vars(opt), 'objects' : objects},
start_fresh=opt.fresh
)
# get state from checkpoint
state = checkpoint.initialize({'epoch': 0, 'model': model.state_dict()})
model.load_state_dict(state['model'])
opt.epoch_start = state['epoch']
### Justin:
print("Model State:")
for parms in model.state_dict():
print(parms,"\t",model.state_dict()[parms].size() )
np_parms = model.state_dict()[parms].numpy()
np.savetxt('pe.coors.txt',np_parms)
### EOF Justin
adj = {}
for inputs, _ in data:
for row in inputs:
x = row[0].item()
y = row[1].item()
if x in adj:
adj[x].add(y)
else:
adj[x] = {y}
controlQ, logQ = mp.Queue(), mp.Queue()
control_thread = mp.Process(target=async_eval, args=(adj, controlQ, logQ, opt))
control_thread.start()
# control closure
def control(model, epoch, elapsed, loss):
"""
Control thread to evaluate embedding
"""
lt = model.w_avg if hasattr(model, 'w_avg') else model.lt.weight.data
manifold.normalize(lt)
checkpoint.path = f'{opt.checkpoint}.{epoch}'
checkpoint.save({
'model': model.state_dict(),
'embeddings': lt,
'epoch': epoch +1, ### Justin
'manifold': opt.manifold,
})
controlQ.put((epoch, elapsed, loss, checkpoint.path))
while not logQ.empty():
lmsg, pth = logQ.get()
shutil.move(pth, opt.checkpoint)
log.info(f'json_stats: {json.dumps(lmsg)}')
control.checkpoint = True
model = model.to(device)
if hasattr(model, 'w_avg'):
model.w_avg = model.w_avg.to(device)
if opt.train_threads > 1:
threads = []
model = model.share_memory()
args = (device, model, data, optimizer, opt, log)
kwargs = {'ctrl': control, 'progress' : not opt.quiet}
for i in range(opt.train_threads):
kwargs['rank'] = i
threads.append(mp.Process(target=train.train, args=args, kwargs=kwargs))
threads[-1].start()
[t.join() for t in threads]
else:
train.train(device, model, data, optimizer, opt, log, ctrl=control,
progress=not opt.quiet)
controlQ.put(None)
control_thread.join()
while not logQ.empty():
lmsg, pth = logQ.get()
shutil.move(pth, opt.checkpoint)
log.info(f'json_stats: {json.dumps(lmsg)}')
def main():
parser = argparse.ArgumentParser(description='Train Hyperbolic Embeddings')
parser.add_argument('-checkpoint', default='/tmp/hype_embeddings.pth',
help='Where to store the model checkpoint')
parser.add_argument('-dset', type=str, required=True,
help='Dataset identifier')
parser.add_argument('-dim', type=int, default=20,
help='Embedding dimension')
parser.add_argument('-manifold', type=str, default='lorentz',
choices=MANIFOLDS.keys())
parser.add_argument('-model', type=str, default='distance',
choices=MODELS.keys(), help='Energy function model')
parser.add_argument('-lr', type=float, default=1000,
help='Learning rate')
parser.add_argument('-epochs', type=int, default=100,
help='Number of epochs')
parser.add_argument('-batchsize', type=int, default=12800,
help='Batchsize')
parser.add_argument('-negs', type=int, default=50,
help='Number of negatives')
parser.add_argument('-burnin', type=int, default=20,
help='Epochs of burn in')
parser.add_argument('-dampening', type=float, default=0.75,
help='Sample dampening during burnin')
parser.add_argument('-ndproc', type=int, default=8,
help='Number of data loading processes')
parser.add_argument('-eval_each', type=int, default=1,
help='Run evaluation every n-th epoch')
parser.add_argument('-fresh', action='store_true', default=False,
help='Override checkpoint')
parser.add_argument('-debug', action='store_true', default=False,
help='Print debuggin output')
parser.add_argument('-gpu', default=0, type=int,
help='Which GPU to run on (-1 for no gpu)')
parser.add_argument('-sym', action='store_true', default=False,
help='Symmetrize dataset')
parser.add_argument('-maxnorm', '-no-maxnorm', default='500000',
action=Unsettable, type=int)
parser.add_argument('-sparse', default=False, action='store_true',
help='Use sparse gradients for embedding table')
parser.add_argument('-burnin_multiplier', default=0.01, type=float)
parser.add_argument('-neg_multiplier', default=1.0, type=float)
parser.add_argument('-quiet', action='store_true', default=False)
parser.add_argument('-lr_type', choices=['scale', 'constant'], default='constant')
parser.add_argument('-train_threads', type=int, default=1,
help='Number of threads to use in training')
parser.add_argument('-margin', type=float, default=0.1, help='Hinge margin')
parser.add_argument('-eval', choices=['reconstruction', 'hypernymy'],
default='reconstruction', help='Which type of eval to perform')
opt = parser.parse_args()
# setup debugging and logigng
log_level = logging.DEBUG if opt.debug else logging.INFO
log = logging.getLogger('poincare')
logging.basicConfig(level=log_level, format='%(message)s', stream=sys.stdout)
# attempt to find GPU
if opt.gpu >= 0 and opt.train_threads > 1:
opt.gpu = -1
log.warning(f'Specified hogwild training with GPU, defaulting to CPU...')
# set default tensor type
if opt.gpu == -1:
th.set_default_tensor_type('torch.DoubleTensor')
if opt.gpu == 1:
th.set_default_tensor_type('torch.cuda.DoubleTensor')
# set device
device = th.device(f'cuda:{opt.gpu-1}' if opt.gpu >= 0 else 'cpu')
print(f"\n\n opt.gpu = {opt.gpu} \n DEVICE = {device} \n\n")
# read data (edge set is fed as .csv in train_nouns.sh)
if 'csv' in opt.dset:
log.info('Using edge list dataloader')
idx, objects, weights = load_edge_list(opt.dset, opt.sym)
data = BatchedDataset(idx, objects, weights, opt.negs, opt.batchsize,
opt.ndproc, opt.burnin > 0, opt.dampening)
else:
log.info('Using adjacency matrix dataloader')
dset = load_adjacency_matrix(opt.dset, 'hdf5')
log.info('Setting up dataset...')
data = AdjacencyDataset(dset, opt.negs, opt.batchsize, opt.ndproc,
opt.burnin > 0, sample_dampening=opt.dampening)
objects = dset['objects']
# create model - read buld_model fn in /hype/__init__.py to see how mfold,
# dim, loss etc are set up. We store these in model below
# (model is object of DistanceEnergyFunction class which inherits from EnergyFunction class)
model = build_model(opt, len(objects))
log.info(f'model is = {model}')
# set burnin parameters
data.neg_multiplier = opt.neg_multiplier
train._lr_multiplier = opt.burnin_multiplier
# Build config string for log
log.info(f'json_conf: {json.dumps(vars(opt))}')
# adjust lr (train_nouns.sh defines opt.lr_type as constant)
if opt.lr_type == 'scale':
opt.lr = opt.lr * opt.batchsize
# Read model params dict. The model is DistanceEnergyFunction
# (see hype/__init__.py for reason why this is the model)
# Read EnergyFunction class to see what these params are - they are
# the expected input to RiemannianSGD class
log.info(f'\n\n------------------------------\nCheck expm, logm, ptransp defined for Poincare. \nBound method should belong to PoincareManifold not EuclideanManifold\n------------------------------\n\n')
log.info(f'Model expm = {model.optim_params()[0]["expm"]}')
log.info(f'Model logm = {model.optim_params()[0]["logm"]}')
log.info(f'Model ptransp = {model.optim_params()[0]["ptransp"]}')
log.info(f'Model rgrad = {model.optim_params()[0]["rgrad"]}')
# setup optimizer
optimizer = RiemannianSGD(model.optim_params(), lr=opt.lr)
# setup checkpoint
checkpoint = LocalCheckpoint(
opt.checkpoint,
include_in_all={'conf' : vars(opt), 'objects' : objects},
start_fresh=opt.fresh
)
# get state from checkpoint
state = checkpoint.initialize({'epoch': 0, 'model': model.state_dict()})
model.load_state_dict(state['model'])
opt.epoch_start = state['epoch']
adj = {}
for inputs, _ in data:
for row in inputs:
x = row[0].item()
y = row[1].item()
if x in adj:
adj[x].add(y)
else:
adj[x] = {y}
controlQ, logQ = mp.Queue(), mp.Queue()
control_thread = mp.Process(target=async_eval, args=(adj, controlQ, logQ, opt))
control_thread.start()
# control closure
def control(model, epoch, elapsed, loss):
"""
Control thread to evaluate embedding
"""
lt = model.w_avg if hasattr(model, 'w_avg') else model.lt.weight.data
model.manifold.normalize(lt)
checkpoint.path = f'{opt.checkpoint}.{epoch}'
checkpoint.save({
'model': model.state_dict(),
'embeddings': lt,
'epoch': epoch,
'model_type': opt.model,
})
controlQ.put((epoch, elapsed, loss, checkpoint.path))
while not logQ.empty():
lmsg, pth = logQ.get()
shutil.move(pth, opt.checkpoint)
if lmsg['best']:
shutil.copy(opt.checkpoint, opt.checkpoint + '.best')
log.info(f'json_stats: {json.dumps(lmsg)}')
control.checkpoint = True
model = model.to(device)
if hasattr(model, 'w_avg'):
model.w_avg = model.w_avg.to(device)
if opt.train_threads > 1:
log.info("multi-threaded")
threads = []
model = model.share_memory()
args = (device, model, data, optimizer, opt, log)
kwargs = {'ctrl': control, 'progress' : not opt.quiet}
for i in range(opt.train_threads):
kwargs['rank'] = i
threads.append(mp.Process(target=train.train, args=args, kwargs=kwargs))
threads[-1].start()
[t.join() for t in threads]
else:
log.info("single-threaded")
train.train(device, model, data, optimizer, opt, log, ctrl=control,
progress=not opt.quiet)
controlQ.put(None)
control_thread.join()
while not logQ.empty():
lmsg, pth = logQ.get()
shutil.move(pth, opt.checkpoint)
log.info(f'json_stats: {json.dumps(lmsg)}')