def add_args(parser: argparse.ArgumentParser): parser.add_argument('--miner.learning_rate', default=0.01, type=float, help='Training initial learning rate.') parser.add_argument('--miner.momentum', default=0.9, type=float, help='Training initial momentum for SGD.') parser.add_argument('--miner.n_epochs', default=int(sys.maxsize), type=int, help='Number of training epochs.') parser.add_argument( '--miner.epoch_length', default=int(sys.maxsize), type=int, help='Iterations of training per epoch (or dataset EOF)') parser.add_argument('--miner.batch_size_train', default=64, type=int, help='Training batch size.') parser.add_argument('--miner.batch_size_test', default=64, type=int, help='Testing batch size.') parser.add_argument('--miner.log_interval', default=150, type=int, help='Batches until miner prints log statements.') parser.add_argument( '--miner.sync_interval', default=10, type=int, help='Batches before we we sync with chain and emit new weights.') parser.add_argument( '--miner.root_dir', default='~/.bittensor/miners/', type=str, help='Root path to load and save data associated with each miner') parser.add_argument( '--miner.name', default='mnist', type=str, help='Trials for this miner go in miner.root / miner.name') parser.add_argument( '--miner.trial_uid', default=str(time.time()).split('.')[0], type=str, help='Saved models go in miner.root_dir / miner.name / miner.uid') parser.add_argument('--miner.record_log', default=False, help='Record all logs when running this miner') parser.add_argument( '--miner.config_file', type=str, help= 'config file to run this neuron, if not using cmd line arguments.') bittensor.neuron.Neuron.add_args(parser) FFNNSynapse.add_args(parser)
def __init__(self, config: Munch = None, **kwargs): if config == None: config = Miner.default_config() bittensor.config.Config.update_with_kwargs(config.miner, kwargs) Miner.check_config(config) self.config = config # ---- Build Neuron ---- self.neuron = bittensor.neuron.Neuron(config) # ---- Build FFNN Model ---- self.model = FFNNSynapse(self.config) self.model.to( torch.device("cuda" if torch.cuda.is_available() else "cpu")) self.neuron.axon.serve(self.model) # ---- Optimizer ---- self.optimizer = torch.optim.SGD(self.model.parameters(), lr=self.config.miner.learning_rate, momentum=self.config.miner.momentum) # ---- Model Load/Save tools ---- self.model_toolbox = ModelToolbox(FFNNSynapse, torch.optim.SGD) # ---- Logging ---- self.tensorboard = SummaryWriter(log_dir=self.config.miner.full_path) if self.config.miner.record_log: logger.add( self.config.miner.full_path + "/{}_{}.log".format( self.config.miner.name, self.config.miner.trial_uid), format="{time:YYYY-MM-DD at HH:mm:ss} | {level} | {message}")
def __init__(self, config: Munch): if config == None: config = Session.build_config() self.config = config # ---- Neuron ---- self.neuron = Neuron(self.config) # ---- Model ---- self.model = FFNNSynapse( config ) # Feedforward neural network with PKMRouter. self.device = torch.device("cuda" if torch.cuda.is_available() else "cpu") self.model.to( self.device ) # Set model to device # ---- Optimizer ---- self.optimizer = optim.SGD(self.model.parameters(), lr=self.config.session.learning_rate, momentum=self.config.session.momentum) self.scheduler = torch.optim.lr_scheduler.StepLR(self.optimizer, step_size=10.0, gamma=0.1) # ---- Dataset ---- self.train_data = torchvision.datasets.MNIST(root = self.config.session.root_dir + "datasets/", train=True, download=True, transform=transforms.ToTensor()) self.trainloader = torch.utils.data.DataLoader(self.train_data, batch_size = self.config.session.batch_size_train, shuffle=True, num_workers=2) self.test_data = torchvision.datasets.MNIST(root = self.config.session.root_dir + "datasets/", train=False, download=True, transform=transforms.ToTensor()) self.testloader = torch.utils.data.DataLoader(self.test_data, batch_size = self.config.session.batch_size_test, shuffle=False, num_workers=2) # ---- Tensorboard ---- self.global_step = 0 self.tensorboard = SummaryWriter(log_dir = self.config.session.full_path)
def __init__(self, config: Munch = None, **kwargs): if config == None: config = Miner.default_config() bittensor.config.Config.update_with_kwargs(config.miner, kwargs) Miner.check_config(config) self.config = config # ---- Neuron ---- self.neuron = bittensor.neuron.Neuron(self.config) # ---- Model ---- self.model = FFNNSynapse( config) # Feedforward neural network with PKMRouter. self.device = torch.device( "cuda" if torch.cuda.is_available() else "cpu") self.model.to(self.device) # Set model to device # ---- Optimizer ---- self.optimizer = optim.SGD(self.model.parameters(), lr=self.config.miner.learning_rate, momentum=self.config.miner.momentum) self.scheduler = torch.optim.lr_scheduler.StepLR(self.optimizer, step_size=10.0, gamma=0.1) # ---- Model Load/Save tools ---- self.model_toolbox = ModelToolbox(FFNNSynapse, optim.SGD) # ---- Dataset ---- self.train_data = torchvision.datasets.MNIST( root=self.config.miner.root_dir + "datasets/", train=True, download=True, transform=transforms.ToTensor()) self.trainloader = torch.utils.data.DataLoader( self.train_data, batch_size=self.config.miner.batch_size_train, shuffle=True, num_workers=2) self.test_data = torchvision.datasets.MNIST( root=self.config.miner.root_dir + "datasets/", train=False, download=True, transform=transforms.ToTensor()) self.testloader = torch.utils.data.DataLoader( self.test_data, batch_size=self.config.miner.batch_size_test, shuffle=False, num_workers=2) # ---- Tensorboard ---- self.global_step = 0 self.tensorboard = SummaryWriter(log_dir=self.config.miner.full_path) if self.config.miner.record_log: logger.add( self.config.miner.full_path + "/{}_{}.log".format( self.config.miner.name, self.config.miner.trial_uid), format="{time:YYYY-MM-DD at HH:mm:ss} | {level} | {message}")
def check_config(config: Munch): assert config.miner.momentum > 0 and config.miner.momentum < 1, "momentum must be a value between 0 and 1" assert config.miner.learning_rate > 0, "learning rate must be be a positive value." full_path = '{}/{}/{}/'.format(config.miner.root_dir, config.miner.name, config.miner.trial_uid) config.miner.full_path = os.path.expanduser(full_path) if not os.path.exists(config.miner.full_path): os.makedirs(config.miner.full_path) FFNNSynapse.check_config(config) bittensor.neuron.Neuron.check_config(config)
def check_config(config: Munch): assert config.session.log_interval > 0, "log_interval dimension must be positive" assert config.session.momentum > 0 and config.session.momentum < 1, "momentum must be a value between 0 and 1" assert config.session.batch_size_train > 0, "batch_size_train must be a positive value" assert config.session.batch_size_test > 0, "batch_size_test must be a positive value" assert config.session.learning_rate > 0, "learning rate must be be a positive value." full_path = '{}/{}/{}/'.format(config.session.root_dir, config.session.name, config.session.uid) config.session.full_path = full_path if not os.path.exists(config.session.full_path): os.makedirs(config.session.full_path) FFNNSynapse.check_config(config) Neuron.check_config(config)
def add_args(parser: argparse.ArgumentParser): parser.add_argument('--session.learning_rate', default=0.01, type=float, help='Training initial learning rate.') parser.add_argument('--session.momentum', default=0.9, type=float, help='Training initial momentum for SGD.') parser.add_argument('--session.batch_size_train', default=64, type=int, help='Training batch size.') parser.add_argument('--session.batch_size_test', default=64, type=int, help='Testing batch size.') parser.add_argument('--session.log_interval', default=150, type=int, help='Batches until session prints log statements.') parser.add_argument('--session.sync_interval', default=150, type=int, help='Batches before we we sync with chain and emit new weights.') parser.add_argument('--session.root_dir', default='data/', type=str, help='Root path to load and save data associated with each session') parser.add_argument('--session.name', default='mnist', type=str, help='Trials for this session go in session.root / session.name') parser.add_argument('--session.uid', default=str(time.time()).split('.')[0], type=str, help='Saved models go in session.root_dir / session.name / session.uid') Neuron.add_args(parser) FFNNSynapse.add_args(parser)
class Miner(): def __init__(self, config: Munch = None, **kwargs): if config == None: config = Miner.default_config() bittensor.config.Config.update_with_kwargs(config.miner, kwargs) Miner.check_config(config) self.config = config # ---- Neuron ---- self.neuron = bittensor.neuron.Neuron(self.config) # ---- Model ---- self.model = FFNNSynapse( config) # Feedforward neural network with PKMRouter. self.device = torch.device( "cuda" if torch.cuda.is_available() else "cpu") self.model.to(self.device) # Set model to device # ---- Optimizer ---- self.optimizer = optim.SGD(self.model.parameters(), lr=self.config.miner.learning_rate, momentum=self.config.miner.momentum) self.scheduler = torch.optim.lr_scheduler.StepLR(self.optimizer, step_size=10.0, gamma=0.1) # ---- Model Load/Save tools ---- self.model_toolbox = ModelToolbox(FFNNSynapse, optim.SGD) # ---- Dataset ---- self.train_data = torchvision.datasets.MNIST( root=self.config.miner.root_dir + "datasets/", train=True, download=True, transform=transforms.ToTensor()) self.trainloader = torch.utils.data.DataLoader( self.train_data, batch_size=self.config.miner.batch_size_train, shuffle=True, num_workers=2) self.test_data = torchvision.datasets.MNIST( root=self.config.miner.root_dir + "datasets/", train=False, download=True, transform=transforms.ToTensor()) self.testloader = torch.utils.data.DataLoader( self.test_data, batch_size=self.config.miner.batch_size_test, shuffle=False, num_workers=2) # ---- Tensorboard ---- self.global_step = 0 self.tensorboard = SummaryWriter(log_dir=self.config.miner.full_path) if self.config.miner.record_log: logger.add( self.config.miner.full_path + "/{}_{}.log".format( self.config.miner.name, self.config.miner.trial_uid), format="{time:YYYY-MM-DD at HH:mm:ss} | {level} | {message}") @staticmethod def default_config() -> Munch: parser = argparse.ArgumentParser() Miner.add_args(parser) config = bittensor.config.Config.to_config(parser) return config @staticmethod def add_args(parser: argparse.ArgumentParser): parser.add_argument('--miner.learning_rate', default=0.01, type=float, help='Training initial learning rate.') parser.add_argument('--miner.momentum', default=0.9, type=float, help='Training initial momentum for SGD.') parser.add_argument('--miner.n_epochs', default=int(sys.maxsize), type=int, help='Number of training epochs.') parser.add_argument( '--miner.epoch_length', default=int(sys.maxsize), type=int, help='Iterations of training per epoch (or dataset EOF)') parser.add_argument('--miner.batch_size_train', default=64, type=int, help='Training batch size.') parser.add_argument('--miner.batch_size_test', default=64, type=int, help='Testing batch size.') parser.add_argument('--miner.log_interval', default=150, type=int, help='Batches until miner prints log statements.') parser.add_argument( '--miner.sync_interval', default=10, type=int, help='Batches before we we sync with chain and emit new weights.') parser.add_argument( '--miner.root_dir', default='~/.bittensor/miners/', type=str, help='Root path to load and save data associated with each miner') parser.add_argument( '--miner.name', default='mnist', type=str, help='Trials for this miner go in miner.root / miner.name') parser.add_argument( '--miner.trial_uid', default=str(time.time()).split('.')[0], type=str, help='Saved models go in miner.root_dir / miner.name / miner.uid') parser.add_argument('--miner.record_log', default=False, help='Record all logs when running this miner') parser.add_argument( '--miner.config_file', type=str, help= 'config file to run this neuron, if not using cmd line arguments.') bittensor.neuron.Neuron.add_args(parser) FFNNSynapse.add_args(parser) @staticmethod def check_config(config: Munch): assert config.miner.log_interval > 0, "log_interval dimension must be positive" assert config.miner.momentum > 0 and config.miner.momentum < 1, "momentum must be a value between 0 and 1" assert config.miner.batch_size_train > 0, "batch_size_train must be a positive value" assert config.miner.batch_size_test > 0, "batch_size_test must be a positive value" assert config.miner.learning_rate > 0, "learning rate must be be a positive value." full_path = '{}/{}/{}/'.format(config.miner.root_dir, config.miner.name, config.miner.trial_uid) config.miner.full_path = os.path.expanduser(full_path) if not os.path.exists(config.miner.full_path): os.makedirs(config.miner.full_path) # --- Main loop ---- def run(self): # ---- Subscribe neuron ---- with self.neuron: # ---- Weights ---- self.row = self.neuron.metagraph.row.to(self.model.device) # --- Loop for epochs --- self.best_test_loss = math.inf self.global_step = 0 for self.epoch in range(self.config.miner.n_epochs): # ---- Serve ---- self.neuron.axon.serve(self.model) # ---- Train ---- self.train() self.scheduler.step() # If model has borked for some reason, we need to make sure it doesn't emit weights # Instead, reload into previous version of model if torch.any( torch.isnan( torch.cat([ param.view(-1) for param in self.model.parameters() ]))): self.model, self.optimizer = self.model_toolbox.load_model( self.config) continue # ---- Test ---- test_loss, test_accuracy = self.test() # ---- Emit ---- self.neuron.metagraph.set_weights( self.row, wait_for_inclusion=True ) # Sets my row-weights on the chain. # ---- Sync ---- self.neuron.metagraph.sync( ) # Pulls the latest metagraph state (with my update.) self.row = self.neuron.metagraph.row.to(self.device) # --- Display Epoch ---- print(self.neuron.axon.__full_str__()) print(self.neuron.dendrite.__full_str__()) print(self.neuron.metagraph) # ---- Update Tensorboard ---- self.neuron.dendrite.__to_tensorboard__( self.tensorboard, self.global_step) self.neuron.metagraph.__to_tensorboard__( self.tensorboard, self.global_step) self.neuron.axon.__to_tensorboard__(self.tensorboard, self.global_step) # ---- Save ---- if test_loss < self.best_test_loss: self.best_test_loss = test_loss # Update best loss. self.model_toolbox.save_model( self.config.miner.full_path, { 'epoch': self.epoch, 'model_state_dict': self.model.state_dict(), 'loss': self.best_test_loss, 'optimizer_state_dict': self.optimizer.state_dict(), }) self.tensorboard.add_scalar('Test loss', test_loss, self.global_step) # ---- Train epoch ---- def train(self): # ---- Init training state ---- self.model.train() # Turn on dropout etc. for batch_idx, (images, targets) in enumerate(self.trainloader): if batch_idx >= self.config.miner.epoch_length: break self.global_step += 1 # ---- Remote Forward pass ---- output = self.model.remote_forward( neuron=self.neuron, images=images.to(self.device), targets=torch.LongTensor(targets).to(self.device), ) # ---- Remote Backward pass ---- loss = output.remote_target_loss + output.local_target_loss + output.distillation_loss loss.backward() # Accumulates gradients on the model. self.optimizer.step() # Applies accumulated gradients. self.optimizer.zero_grad( ) # Zeros out gradients for next accummulation # ---- Train weights ---- batch_weights = torch.mean(output.router.weights, axis=0).to( self.model.device) # Average over batch. self.row = ( 1 - 0.03) * self.row + 0.03 * batch_weights # Moving avg update. self.row = F.normalize(self.row, p=1, dim=0) # Ensure normalization. # ---- Step Logs + Tensorboard ---- processed = ((batch_idx + 1) * self.config.miner.batch_size_train) progress = (100. * processed) / len(self.train_data) logger.info( 'GS: {}\t Epoch: {} [{}/{} ({})]\tLoss: {}\tAcc: {}\tAxon: {}\tDendrite: {}', colored('{}'.format(self.global_step), 'blue'), colored('{}'.format(self.epoch), 'blue'), colored('{}'.format(processed), 'green'), colored('{}'.format(len(self.train_data)), 'red'), colored('{:.2f}%'.format(progress), 'green'), colored('{:.4f}'.format(output.local_target_loss.item()), 'green'), colored('{:.4f}'.format(output.local_accuracy.item()), 'green'), self.neuron.axon, self.neuron.dendrite) self.tensorboard.add_scalar('Rloss', output.remote_target_loss.item(), self.global_step) self.tensorboard.add_scalar('Lloss', output.local_target_loss.item(), self.global_step) self.tensorboard.add_scalar('Dloss', output.distillation_loss.item(), self.global_step) # --- Test epoch ---- def test(self): with torch.no_grad( ): # Turns off gradient computation for inference speed up. self.model.eval() # Turns off Dropoutlayers, BatchNorm etc. loss = 0.0 accuracy = 0.0 for _, (images, labels) in enumerate(self.testloader): # ---- Local Forward pass ---- outputs = self.model.local_forward( images=images.to(self.device), targets=torch.LongTensor(labels).to(self.device), ) loss += outputs.local_target_loss.item() accuracy += outputs.local_accuracy.item() return loss / len(self.testloader), accuracy / len(self.testloader)
class Session(): def __init__(self, config: Munch): if config == None: config = Session.default_config() self.config = config # ---- Neuron ---- self.neuron = Neuron(self.config) # ---- Model ---- self.model = FFNNSynapse( config) # Feedforward neural network with PKMRouter. self.device = torch.device( "cuda" if torch.cuda.is_available() else "cpu") self.model.to(self.device) # Set model to device # ---- Optimizer ---- self.optimizer = optim.SGD(self.model.parameters(), lr=self.config.miner.learning_rate, momentum=self.config.miner.momentum) self.scheduler = torch.optim.lr_scheduler.StepLR(self.optimizer, step_size=10.0, gamma=0.1) # ---- Dataset ---- self.train_data = torchvision.datasets.MNIST( root=self.config.miner.root_dir + "datasets/", train=True, download=True, transform=transforms.ToTensor()) self.trainloader = torch.utils.data.DataLoader( self.train_data, batch_size=self.config.miner.batch_size_train, shuffle=True, num_workers=2) self.test_data = torchvision.datasets.MNIST( root=self.config.miner.root_dir + "datasets/", train=False, download=True, transform=transforms.ToTensor()) self.testloader = torch.utils.data.DataLoader( self.test_data, batch_size=self.config.miner.batch_size_test, shuffle=False, num_workers=2) # ---- Tensorboard ---- self.global_step = 0 self.tensorboard = SummaryWriter(log_dir=self.config.miner.full_path) @staticmethod def default_config() -> Munch: parser = argparse.ArgumentParser() Session.add_args(parser) config = Config.to_config(parser) Session.check_config(config) return config @staticmethod def add_args(parser: argparse.ArgumentParser): parser.add_argument('--session.learning_rate', default=0.01, type=float, help='Training initial learning rate.') parser.add_argument('--session.momentum', default=0.9, type=float, help='Training initial momentum for SGD.') parser.add_argument('--session.batch_size_train', default=64, type=int, help='Training batch size.') parser.add_argument('--session.batch_size_test', default=64, type=int, help='Testing batch size.') parser.add_argument( '--session.log_interval', default=150, type=int, help='Batches until session prints log statements.') parser.add_argument( '--session.sync_interval', default=150, type=int, help='Batches before we we sync with chain and emit new weights.') parser.add_argument( '--session.root_dir', default='data/', type=str, help='Root path to load and save data associated with each session' ) parser.add_argument( '--session.name', default='mnist', type=str, help='Trials for this session go in session.root / session.name') parser.add_argument( '--session.uid', default=str(time.time()).split('.')[0], type=str, help= 'Saved models go in session.root_dir / session.name / session.uid') Neuron.add_args(parser) FFNNSynapse.add_args(parser) @staticmethod def check_config(config: Munch): assert config.miner.log_interval > 0, "log_interval dimension must be positive" assert config.miner.momentum > 0 and config.miner.momentum < 1, "momentum must be a value between 0 and 1" assert config.miner.batch_size_train > 0, "batch_size_train must be a positive value" assert config.miner.batch_size_test > 0, "batch_size_test must be a positive value" assert config.miner.learning_rate > 0, "learning rate must be be a positive value." full_path = '{}/{}/{}/'.format(config.miner.root_dir, config.miner.name, config.miner.uid) config.miner.full_path = full_path if not os.path.exists(config.miner.full_path): os.makedirs(config.miner.full_path) FFNNSynapse.check_config(config) Neuron.check_config(config) # --- Main loop ---- def run(self): # ---- Subscribe neuron ---- with self.neuron: # ---- Loop forever ---- start_time = time.time() self.epoch = -1 self.best_test_loss = math.inf self.global_step = 0 self.weights = self.neuron.metagraph.row # Trained weights. while True: self.epoch += 1 # ---- Emit ---- self.neuron.metagraph.set_weights( self.weights, wait_for_inclusion=True ) # Sets my row-weights on the chain. # ---- Sync ---- self.neuron.metagraph.sync( ) # Pulls the latest metagraph state (with my update.) self.weights = self.neuron.metagraph.row.to(self.device) # ---- Train ---- self.train() self.scheduler.step() # ---- Test ---- test_loss, test_accuracy = self.test() # ---- Test checks ---- time_elapsed = time.time() - start_time assert test_accuracy > 0.8 assert test_loss < 0.2 assert len(self.neuron.metagraph.state.neurons) > 0 assert time_elapsed < 300 # 1 epoch of MNIST should take less than 5 mins. # ---- End test ---- break # ---- Train epoch ---- def train(self): # ---- Init training state ---- self.model.train() # Turn on dropout etc. for batch_idx, (images, targets) in enumerate(self.trainloader): self.global_step += 1 # ---- Remote Forward pass ---- output = self.model.remote_forward( neuron=self.neuron, images=images.to(self.device), targets=torch.LongTensor(targets).to(self.device), ) # ---- Remote Backward pass ---- loss = output.remote_target_loss + output.local_target_loss + output.distillation_loss loss.backward() # Accumulates gradients on the model. self.optimizer.step() # Applies accumulated gradients. self.optimizer.zero_grad( ) # Zeros out gradients for next accummulation # ---- Train weights ---- batch_weights = torch.mean(output.router.weights, axis=0) # Average over batch. self.weights = ( 1 - 0.03 ) * self.weights + 0.03 * batch_weights # Moving avg update. self.weights = F.normalize(self.weights, p=1, dim=0) # Ensure normalization. # ---- Step Logs + Tensorboard ---- processed = ((batch_idx + 1) * self.config.miner.batch_size_train) progress = (100. * processed) / len(self.train_data) logger.info( 'GS: {}\t Epoch: {} [{}/{} ({})]\t Loss: {}\t Acc: {}\t Axon: {}\t Dendrite: {}', colored('{}'.format(self.global_step), 'blue'), colored('{}'.format(self.epoch), 'blue'), colored('{}'.format(processed), 'green'), colored('{}'.format(len(self.train_data)), 'red'), colored('{:.2f}%'.format(progress), 'green'), colored('{:.4f}'.format(output.local_target_loss.item()), 'green'), colored('{:.4f}'.format(output.local_accuracy.item()), 'green'), self.neuron.axon, self.neuron.dendrite) self.tensorboard.add_scalar('Rloss', output.remote_target_loss.item(), self.global_step) self.tensorboard.add_scalar('Lloss', output.local_target_loss.item(), self.global_step) self.tensorboard.add_scalar('Dloss', output.distillation_loss.item(), self.global_step) # --- Test epoch ---- def test(self): with torch.no_grad( ): # Turns off gradient computation for inference speed up. self.model.eval() # Turns off Dropoutlayers, BatchNorm etc. loss = 0.0 accuracy = 0.0 for _, (images, labels) in enumerate(self.testloader): # ---- Local Forward pass ---- outputs = self.model.local_forward( images=images.to(self.device), targets=torch.LongTensor(labels).to(self.device), ) loss += outputs.local_target_loss.item() accuracy += outputs.local_accuracy.item() return loss / len(self.testloader), accuracy / len(self.testloader)
class Miner(): def __init__(self, config: Munch = None, **kwargs): if config == None: config = Miner.default_config() bittensor.config.Config.update_with_kwargs(config.miner, kwargs) Miner.check_config(config) self.config = config # ---- Build Neuron ---- self.neuron = bittensor.neuron.Neuron(config) # ---- Build FFNN Model ---- self.model = FFNNSynapse(self.config) self.model.to( torch.device("cuda" if torch.cuda.is_available() else "cpu")) self.neuron.axon.serve(self.model) # ---- Optimizer ---- self.optimizer = torch.optim.SGD(self.model.parameters(), lr=self.config.miner.learning_rate, momentum=self.config.miner.momentum) # ---- Model Load/Save tools ---- self.model_toolbox = ModelToolbox(FFNNSynapse, torch.optim.SGD) # ---- Logging ---- self.tensorboard = SummaryWriter(log_dir=self.config.miner.full_path) if self.config.miner.record_log: logger.add( self.config.miner.full_path + "/{}_{}.log".format( self.config.miner.name, self.config.miner.trial_uid), format="{time:YYYY-MM-DD at HH:mm:ss} | {level} | {message}") @staticmethod def default_config() -> Munch: parser = argparse.ArgumentParser() Miner.add_args(parser) config = bittensor.config.Config.to_config(parser) return config @staticmethod def add_args(parser: argparse.ArgumentParser): parser.add_argument('--miner.learning_rate', default=0.01, type=float, help='Training initial learning rate.') parser.add_argument('--miner.momentum', default=0.9, type=float, help='Training initial momentum for SGD.') parser.add_argument('--miner.n_epochs', default=int(sys.maxsize), type=int, help='Number of training epochs.') parser.add_argument( '--miner.sync_interval', default=150, type=int, help='Batches before we we sync with chain and emit new weights.') parser.add_argument( '--miner.root_dir', default='~/.bittensor/miners/', type=str, help='Root path to load and save data associated with each miner') parser.add_argument( '--miner.name', default='ffnn-grunt', type=str, help='Trials for this miner go in miner.root / miner.name') parser.add_argument( '--miner.trial_uid', default=str(time.time()).split('.')[0], type=str, help='Saved models go in miner.root_dir / miner.name / miner.uid') parser.add_argument('--miner.record_log', default=False, help='Record all logs when running this miner') parser.add_argument( '--miner.config_file', type=str, help= 'config file to run this neuron, if not using cmd line arguments.') bittensor.neuron.Neuron.add_args(parser) FFNNSynapse.add_args(parser) @staticmethod def check_config(config: Munch): assert config.miner.momentum > 0 and config.miner.momentum < 1, "momentum must be a value between 0 and 1" assert config.miner.learning_rate > 0, "learning rate must be be a positive value." full_path = '{}/{}/{}/'.format(config.miner.root_dir, config.miner.name, config.miner.trial_uid) config.miner.full_path = os.path.expanduser(full_path) if not os.path.exists(config.miner.full_path): os.makedirs(config.miner.full_path) # ---- Main loop ---- def run(self): # --- Subscribe / Update neuron --- with self.neuron: # ---- Loop for epochs ---- self.model.train() for self.epoch in range(self.config.miner.n_epochs): # ---- Poll until gradients ---- public_key, inputs_x, grads_dy, modality_x = self.neuron.axon.gradients.get( block=True) # ---- Backward Gradients ---- # TODO (const): batch normalization over the gradients for consistency. grads_dy = torch.where(torch.isnan(grads_dy), torch.zeros_like(grads_dy), grads_dy) self.model.backward(inputs_x, grads_dy, modality_x) # ---- Apply Gradients ---- self.optimizer.step() # Apply accumulated gradients. self.optimizer.zero_grad() # Clear any lingering gradients # If model has borked for some reason, we need to make sure it doesn't emit weights # Instead, reload into previous version of the model if torch.any( torch.isnan( torch.cat([ param.view(-1) for param in self.model.parameters() ]))): self.model, self.optimizer = self.model_toolbox.load_model( self.config) # ---- Serve latest model ---- self.neuron.axon.serve(self.model) # Serve the newest model. logger.info('Step: {} \t Key: {} \t sum(W[:,0])', self.epoch, public_key, torch.sum(self.neuron.metagraph.col).item()) # ---- Sync State ---- if (self.epoch + 1) % self.config.miner.sync_interval == 0: # --- Display Epoch ---- print(self.neuron.axon.__full_str__()) print(self.neuron.dendrite.__full_str__()) print(self.neuron.metagraph) # ---- Sync metagrapn from chain ---- self.neuron.metagraph.sync() # Sync with the chain. # --- Save Model ---- self.model_toolbox.save_model( self.config.miner.full_path, { 'epoch': self.epoch, 'model_state_dict': self.model.state_dict(), 'optimizer_state_dict': self.optimizer.state_dict(), })