import json import os import sys import types import torch def add_arguments(parser): group = parser.add_argument_group(title='Megatron loader') group.add_argument('--true-vocab-size', type=int, default=None, help='original size of vocab, if specified will trim padding from embedding table.') group.add_argument('--vocab-file', type=str, default=None, help='Path to the vocab file. If specified will use this to get vocab size and ' 'trim padding from the embedding table.') group.add_argument('--megatron-path', type=str, default=None, help='Base directory of deepspeed repository') def _load_checkpoint(queue, args): # Search in directory above this sys.path.append(os.path.abspath( os.path.join(os.path.dirname(__file__), os.path.pardir))) if args.megatron_path is not None: sys.path.insert(0, args.megatron_path) try: from megatron.arguments import parse_args, validate_args from megatron.global_vars import set_args, set_global_variables from megatron.checkpointing import load_args_from_checkpoint, load_checkpoint from megatron.model import module from megatron.core import mpu from megatron.core.enums import ModelType from megatron import fused_kernels except ModuleNotFoundError: print("Unable to import Megatron, please specify the path to Megatron using --megatron-path. Exiting.") queue.put("exit") exit(1) # We want all arguments to come from us sys.argv = ['script.py', '--no-masked-softmax-fusion', '--no-bias-gelu-fusion', '--no-bias-dropout-fusion', '--no-async-tensor-model-parallel-allreduce', '--use-cpu-initialization', '--micro-batch-size', '1', '--no-load-optim', '--no-load-rng', '--no-save-optim', '--no-save-rng', '--no-initialization', '--load', args.load_dir ] margs = parse_args() margs, checkpoint_args = load_args_from_checkpoint(margs) # Arguments do sanity checks on the world size, but we don't care, # so trick it into thinking we are plenty of processes margs.world_size = margs.tensor_model_parallel_size * margs.pipeline_model_parallel_size margs = validate_args(margs) def check_for_arg(arg_name, default=None): if getattr(margs, arg_name, None) is None: if default is not None: setattr(margs, arg_name, default) else: print(f"Checkpoint does not specify the argument {arg_name}. Exiting.") print(f"Arguments: {margs}") queue.put("exit") exit(1) check_for_arg('tensor_model_parallel_size') check_for_arg('pipeline_model_parallel_size') check_for_arg('num_layers') check_for_arg('hidden_size') check_for_arg('seq_length') check_for_arg('num_attention_heads') check_for_arg('max_position_embeddings') check_for_arg('add_position_embedding', True) check_for_arg('use_rotary_position_embeddings', False) check_for_arg('tokenizer_type') check_for_arg('iteration') check_for_arg('bert_binary_head') check_for_arg('disable_bias_linear', False) check_for_arg('params_dtype') check_for_arg('swiglu', False) # Determine how to make our models if args.model_type == 'GPT': from pretrain_gpt import model_provider margs.model_type = ModelType.encoder_or_decoder elif args.model_type == 'BERT': from pretrain_bert import model_provider margs.model_type = ModelType.encoder_or_decoder else: raise Exception(f'unrecognized model type: {args.model_type}') # supress warning about torch.distributed not being initialized module.MegatronModule.embedding_warning_printed = True consumed_train_samples = None consumed_valid_samples = None def get_models(count, dtype): nonlocal consumed_train_samples nonlocal consumed_valid_samples model_array_len = margs.virtual_pipeline_model_parallel_size if model_array_len is None: model_array_len = 1 models = [[] for _ in range(model_array_len)] pre_process = mpu.is_pipeline_first_stage() post_process = mpu.is_pipeline_last_stage() for rank in range(count): mpu.set_tensor_model_parallel_rank(rank) if margs.virtual_pipeline_model_parallel_size is not None: model_ = [] for i in range(margs.virtual_pipeline_model_parallel_size): mpu.set_virtual_pipeline_model_parallel_rank(i) # Set pre_process and post_process only after virtual rank is set. pre_process = mpu.is_pipeline_first_stage() post_process = mpu.is_pipeline_last_stage() this_model = model_provider( pre_process=pre_process, post_process=post_process ).to(dtype) model_.append(this_model) else: pre_process = mpu.is_pipeline_first_stage() post_process = mpu.is_pipeline_last_stage() model_rank = 0 model_ = [model_provider(pre_process, post_process).to(dtype)] margs.consumed_train_samples = 0 margs.consumed_valid_samples = 0 load_checkpoint(model_, None, None) if consumed_train_samples is not None: assert(margs.consumed_train_samples == consumed_train_samples) else: consumed_train_samples = margs.consumed_train_samples if consumed_valid_samples is not None: assert(margs.consumed_valid_samples == consumed_valid_samples) else: consumed_valid_samples = margs.consumed_valid_samples for vp_rank in range(model_array_len): models[vp_rank].append(model_[vp_rank]) return models set_global_variables(margs) mpu.set_tensor_model_parallel_world_size(margs.tensor_model_parallel_size) mpu.set_pipeline_model_parallel_world_size(margs.pipeline_model_parallel_size) mpu.set_virtual_pipeline_model_parallel_world_size(margs.virtual_pipeline_model_parallel_size) fused_kernels.load(margs) # Get true (non-padded) vocab size if args.true_vocab_size is not None: true_vocab_size = args.true_vocab_size elif args.vocab_file is not None: vocab = json.load(open(args.vocab_file)) true_vocab_size = len(vocab) if args.true_vocab_size is not None and true_vocab_size != args.true_vocab_size: print("Both --true-vocab-size and --vocab-file specified and the vocab size does not match, aborting.") queue.put("exit") exit(1) else: true_vocab_size = None # short aliases tp_size = margs.tensor_model_parallel_size pp_size = margs.pipeline_model_parallel_size vp_size = margs.virtual_pipeline_model_parallel_size if vp_size is None: vp_size = 1 # metadata md = types.SimpleNamespace() md.model_type = args.model_type md.num_layers = margs.num_layers md.hidden_size = margs.hidden_size md.seq_length = margs.seq_length md.num_attention_heads = margs.num_attention_heads md.max_position_embeddings = margs.max_position_embeddings md.tokenizer_type = margs.tokenizer_type md.iteration = margs.iteration md.params_dtype = margs.params_dtype md.bert_binary_head = margs.bert_binary_head md.output_layer = margs.untie_embeddings_and_output_weights md.position_embeddings = margs.add_position_embedding md.linear_bias = margs.add_bias_linear md.swiglu = margs.swiglu md.previous_tensor_parallel_size = margs.tensor_model_parallel_size md.previous_pipeline_parallel_size = margs.pipeline_model_parallel_size md.true_vocab_size = true_vocab_size md.make_vocab_size_divisible_by = margs.make_vocab_size_divisible_by md.checkpoint_args = checkpoint_args # Get first pipe stage mpu.set_pipeline_model_parallel_rank(0) all_models = [get_models(tp_size, md.params_dtype)] models = all_models[0][0] md.consumed_train_samples = consumed_train_samples md.consumed_valid_samples = consumed_valid_samples queue.put(md) def queue_put(name, msg): print(f"sending {name}") msg["name"] = name queue.put(msg) # Send embeddings message = { "word embeddings": torch.cat( [models[tp_rank].language_model.embedding.word_embeddings.weight.data for tp_rank in range(tp_size)], dim = 0) } if md.position_embeddings: message["position embeddings"] = models[0].language_model.embedding.position_embeddings.weight.data queue_put("embeddings", message) total_layer_num = 0 for vp_rank in range(vp_size): mpu.set_virtual_pipeline_model_parallel_rank(vp_rank) for pp_rank in range(pp_size): if pp_rank > 0: mpu.set_pipeline_model_parallel_rank(pp_rank) if vp_rank == 0: all_models.append(get_models(tp_size, md.params_dtype)) models = all_models[pp_rank][vp_rank] for layer_num in range(len(models[0].language_model.encoder.layers)): message = {} # Get non-parallel tensors from tp_rank 0 layer = models[0].language_model.encoder.layers[layer_num] message["input layernorm weight"] = layer.input_layernorm.weight.data message["input layernorm bias"] = layer.input_layernorm.bias.data message["post layernorm weight"] = layer.post_attention_layernorm.weight.data message["post layernorm bias"] = layer.post_attention_layernorm.bias.data if md.linear_bias: message["dense bias"] = layer.self_attention.dense.bias.data message["mlp l1 bias"] = layer.mlp.dense_4h_to_h.bias.data # Grab all parallel tensors for this layer qkv_weight = [] qkv_bias = [] dense_weight = [] mlp_l0_weight = [] mlp_l0_bias = [] mlp_l1_weight = [] for tp_rank, model in enumerate(models): layer = model.language_model.encoder.layers[layer_num] qkv_weight.append(layer.self_attention.query_key_value.weight.data) dense_weight.append(layer.self_attention.dense.weight.data) mlp_l0_weight.append(layer.mlp.dense_h_to_4h.weight.data) mlp_l1_weight.append(layer.mlp.dense_4h_to_h.weight.data) if md.linear_bias: qkv_bias.append(layer.self_attention.query_key_value.bias.data) mlp_l0_bias.append(layer.mlp.dense_h_to_4h.bias.data) # Handle gated linear units if md.swiglu: # concat all the first halves ('W's) and all the second halves ('V's) for tp_rank in range(tp_size): mlp_l0_weight[tp_rank] = torch.chunk(mlp_l0_weight[tp_rank], 2, dim=0) message["mlp l0 weight W"] = torch.cat([w[0] for w in mlp_l0_weight], dim=0) message["mlp l0 weight V"] = torch.cat([w[1] for w in mlp_l0_weight], dim=0) else: message["mlp l0 weight"] = torch.cat(mlp_l0_weight, dim=0) # simple concat of the rest message["qkv weight"] = torch.cat(qkv_weight, dim=0) message["dense weight"] = torch.cat(dense_weight, dim=1) message["mlp l1 weight"] = torch.cat(mlp_l1_weight, dim=1) if md.linear_bias: message["qkv bias"] = torch.cat(qkv_bias, dim=0) if md.swiglu: for tp_rank in range(tp_size): mlp_l0_bias[tp_rank] = torch.chunk(mlp_l0_bias[tp_rank], 2, dim=0) message["mlp l0 bias W"] = torch.cat([b[0] for b in mlp_l0_bias],dim=0) message["mlp l0 bias V"] = torch.cat([b[1] for b in mlp_l0_bias],dim=0) else: message["mlp l0 bias"] = torch.cat(mlp_l0_bias, dim=0) queue_put(f"transformer layer {total_layer_num}", message) total_layer_num = total_layer_num + 1 # Send final layernorm from tp_rank 0 message = { "weight": models[0].language_model.encoder.final_layernorm.weight.data, "bias": models[0].language_model.encoder.final_layernorm.bias.data } queue_put("final layernorm", message) if md.output_layer: message = { "weight": torch.cat( [models[tp_rank].language_model.output_layer.weight.data for tp_rank in range(tp_size)], dim = 0) } queue_put("output layer", message) # Send BERT lm head and binary head if it exists if md.model_type == 'BERT': message = { "weight": models[0].language_model.pooler.dense.weight.data, "bias": models[0].language_model.pooler.dense.bias.data } queue_put("pooler", message) message = { "dense weight": models[0].lm_head.dense.weight.data, "dense bias": models[0].lm_head.dense.bias.data, "layernorm weight": models[0].lm_head.layernorm.weight.data, "layernorm bias": models[0].lm_head.layernorm.bias.data } queue_put("lm head", message) if md.bert_binary_head: message = { "weight": models[0].binary_head.weight.data, "bias": models[0].binary_head.bias.data } queue_put("binary head", message) queue.put("done") def load_checkpoint(queue, args): try: _load_checkpoint(queue, args) except: queue.put("exit") raise