import functools import os import shutil import psutil import torch from colossalai.core import global_context as gpc def logging(s, log_path, print_=True, log_=True): if print_: print(s) if log_: with open(log_path, 'a+') as f_log: f_log.write(s + '\n') def get_logger(log_path, **kwargs): return functools.partial(logging, log_path=log_path, **kwargs) def create_exp_dir(dir_path, scripts_to_save=None, debug=False): if debug: print('Debug Mode : no experiment dir created') return functools.partial(logging, log_path=None, log_=False) if not os.path.exists(dir_path): os.makedirs(dir_path) print('Experiment dir : {}'.format(dir_path)) if scripts_to_save is not None: script_path = os.path.join(dir_path, 'scripts') if not os.path.exists(script_path): os.makedirs(script_path) for script in scripts_to_save: dst_file = os.path.join(dir_path, 'scripts', os.path.basename(script)) shutil.copyfile(script, dst_file) return get_logger(log_path=os.path.join(dir_path, 'log.txt')) def get_cpu_mem(): return psutil.Process().memory_info().rss / 1024**2 def get_gpu_mem(): return torch.cuda.memory_allocated() / 1024**2 def get_mem_info(prefix=''): return f'{prefix}GPU memory usage: {get_gpu_mem():.2f} MB, CPU memory usage: {get_cpu_mem():.2f} MB' def get_tflops(model_numel, batch_size, seq_len, step_time): return model_numel * batch_size * seq_len * 8 / 1e12 / (step_time + 1e-12) def get_parameters_in_billions(model, world_size=1): gpus_per_model = world_size approx_parameters_in_billions = sum([ sum([p.ds_numel if hasattr(p, 'ds_id') else p.nelement() for p in model_module.parameters()]) for model_module in model ]) return approx_parameters_in_billions * gpus_per_model / (1e9) def throughput_calculator(numel, args, config, iteration_time, total_iterations, world_size=1): gpus_per_model = 1 batch_size = args.train_micro_batch_size_per_gpu samples_per_model = batch_size * args.max_seq_length model_replica_count = world_size / gpus_per_model approx_parameters_in_billions = numel elapsed_time_per_iter = iteration_time / total_iterations samples_per_second = batch_size / elapsed_time_per_iter #flops calculator hidden_size = config.hidden_size num_layers = config.num_hidden_layers vocab_size = config.vocab_size # General TFLOPs formula (borrowed from Equation 3 in Section 5.1 of # https://arxiv.org/pdf/2104.04473.pdf). # The factor of 4 is when used with activation check-pointing, # otherwise it will be 3. checkpoint_activations_factor = 4 if args.checkpoint_activations else 3 flops_per_iteration = (24 * checkpoint_activations_factor * batch_size * args.max_seq_length * num_layers * (hidden_size**2)) * (1. + (args.max_seq_length / (6. * hidden_size)) + (vocab_size / (16. * num_layers * hidden_size))) tflops = flops_per_iteration / (elapsed_time_per_iter * (10**12)) return samples_per_second, tflops, approx_parameters_in_billions def synchronize(): if not torch.distributed.is_available(): return if not torch.distributed.is_intialized(): return world_size = torch.distributed.get_world_size() if world_size == 1: return torch.distributed.barrier() def log_args(logger, args): logger.info('--------args----------') message = '\n'.join([f'{k:<30}: {v}' for k, v in vars(args).items()]) message += '\n' message += '\n'.join([f'{k:<30}: {v}' for k, v in gpc.config.items()]) logger.info(message) logger.info('--------args----------\n')