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""" |
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Instruction-tuning on the Alpaca dataset using a regular finetuning procedure (updating all layers). |
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Note: If you run into a CUDA error "Expected is_sm80 to be true, but got false", uncomment the line |
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`torch.backends.cuda.enable_flash_sdp(False)` in the script below (see https://github.com/Lightning-AI/lit-llama/issues/101). |
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""" |
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import os |
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import time |
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from functools import partial |
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import lightning as L |
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from lightning.fabric.strategies import FSDPStrategy |
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import numpy as np |
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import torch |
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from torch.distributed.fsdp.wrap import transformer_auto_wrap_policy |
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from generate import generate |
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from lit_llama.model import Block, LLaMA, LLaMAConfig |
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from lit_llama.tokenizer import Tokenizer |
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from lit_llama.utils import save_model_checkpoint |
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from scripts.prepare_alpaca import generate_prompt |
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eval_interval = 1000 |
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save_interval = 1000 |
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eval_iters = 100 |
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log_interval = 100 |
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devices = 4 |
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learning_rate = 3e-5 |
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batch_size = 128 / devices |
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micro_batch_size = 4 |
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gradient_accumulation_steps = batch_size // micro_batch_size |
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epoch_size = 50000 |
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num_epochs = 5 |
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max_iters = num_epochs * epoch_size // micro_batch_size // devices |
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weight_decay = 0.0 |
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block_size = 512 |
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warmup_steps = 100 |
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def main( |
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data_dir: str = "data/alpaca", |
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pretrained_path: str = "checkpoints/lit-llama/7B/lit-llama.pth", |
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out_dir: str = "out/full/alpaca", |
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): |
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auto_wrap_policy = partial(transformer_auto_wrap_policy, transformer_layer_cls={Block}) |
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strategy = FSDPStrategy(auto_wrap_policy=auto_wrap_policy, activation_checkpointing=Block) |
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fabric = L.Fabric(accelerator="cuda", devices=devices, precision="bf16-mixed", strategy=strategy) |
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fabric.launch() |
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fabric.seed_everything(1337 + fabric.global_rank) |
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if fabric.global_rank == 0: |
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os.makedirs(out_dir, exist_ok=True) |
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train_data, val_data = load_datasets(data_dir=data_dir) |
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config = LLaMAConfig.from_name("7B") |
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config.block_size = block_size |
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checkpoint = torch.load(pretrained_path) |
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with fabric.device: |
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torch.set_default_tensor_type(torch.HalfTensor) |
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model = LLaMA(config).bfloat16() |
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torch.set_default_tensor_type(torch.FloatTensor) |
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model.load_state_dict(checkpoint, strict=False) |
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model = fabric.setup_module(model) |
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optimizer = torch.optim.AdamW(model.parameters(), lr=learning_rate) |
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optimizer = fabric.setup_optimizers(optimizer) |
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train(fabric, model, optimizer, train_data, val_data, out_dir) |
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save_model_checkpoint(fabric, model, os.path.join(out_dir, "lit-llama-full-finetuned.pth")) |
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def train( |
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fabric: L.Fabric, |
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model: torch.nn.Module, |
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optimizer: torch.optim.Optimizer, |
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train_data: np.ndarray, |
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val_data: np.ndarray, |
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out_dir: str, |
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) -> None: |
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"""The training loop. |
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Loosely based on the nanoGPT implementation: https://github.com/karpathy/nanoGPT. |
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""" |
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step_count = 0 |
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model.train() |
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for iter_num in range(max_iters): |
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is_accumulating = (iter_num + 1) % gradient_accumulation_steps == 0 |
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if step_count <= warmup_steps: |
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lr = learning_rate * step_count / warmup_steps |
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for param_group in optimizer.param_groups: |
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param_group['lr'] = lr |
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t0 = time.time() |
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with fabric.no_backward_sync(model, enabled=is_accumulating): |
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input_ids, targets = get_batch(fabric, train_data) |
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logits = model(input_ids) |
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loss = loss_fn(logits, targets) |
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fabric.backward(loss) |
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if not is_accumulating: |
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optimizer.step() |
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optimizer.zero_grad() |
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step_count += 1 |
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if step_count % eval_interval == 0: |
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val_loss = validate(fabric, model, val_data) |
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fabric.print(f"step {iter_num}: val loss {val_loss:.4f}") |
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fabric.barrier() |
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if step_count % save_interval == 0: |
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print(f"Saving weights to {out_dir}") |
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save_model_checkpoint(fabric, model, os.path.join(out_dir, f"iter-{iter_num:06d}-ckpt.pth")) |
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dt = time.time() - t0 |
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if iter_num % log_interval == 0: |
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fabric.print(f"iter {iter_num}: loss {loss.item():.4f}, time: {dt*1000:.2f}ms") |
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def generate_response(model, instruction): |
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tokenizer = Tokenizer("checkpoints/lit-llama/tokenizer.model") |
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sample = {"instruction": instruction, "input": ""} |
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prompt = generate_prompt(sample) |
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encoded = tokenizer.encode(prompt, bos=True, eos=False, device=model.device) |
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output = generate( |
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model, |
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idx=encoded, |
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max_seq_length=block_size, |
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max_new_tokens=100, |
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) |
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output = tokenizer.decode(output) |
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return output |
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@torch.no_grad() |
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def validate(fabric: L.Fabric, model: torch.nn.Module, val_data: np.ndarray) -> torch.Tensor: |
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fabric.print("Validating ...") |
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model.eval() |
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losses = torch.zeros(eval_iters) |
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for k in range(eval_iters): |
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input_ids, targets = get_batch(fabric, val_data) |
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logits = model(input_ids) |
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loss = loss_fn(logits, targets) |
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losses[k] = loss.item() |
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out = losses.mean() |
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instruction = "Recommend a movie for me to watch during the weekend and explain the reason." |
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output = generate_response(model, instruction) |
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fabric.print(instruction) |
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fabric.print(output) |
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model.train() |
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return out.item() |
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def loss_fn(logits, targets): |
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logits = logits[..., :-1, :].contiguous() |
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targets = targets[..., 1:].contiguous() |
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loss = torch.nn.functional.cross_entropy(logits.view(-1, logits.size(-1)), targets.view(-1), ignore_index=-1) |
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return loss |
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def get_batch(fabric: L.Fabric, data: list): |
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ix = torch.randint(len(data), (micro_batch_size,)) |
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input_ids = [data[i]["input_ids"].type(torch.int64) for i in ix] |
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labels = [data[i]["labels"].type(torch.int64) for i in ix] |
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max_len = max(len(s) for s in input_ids) |
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def pad_right(x, pad_id): |
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n = max_len - len(x) |
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return torch.cat((x, torch.full((n,), pad_id, dtype=x.dtype))) |
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x = torch.stack([pad_right(x, pad_id=0) for x in input_ids]) |
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y = torch.stack([pad_right(x, pad_id=-1) for x in labels]) |
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x, y = fabric.to_device((x.pin_memory(), y.pin_memory())) |
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return x, y |
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def load_datasets(data_dir): |
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train_data = torch.load(os.path.join(data_dir, "train.pt")) |
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val_data = torch.load(os.path.join(data_dir, "test.pt")) |
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return train_data, val_data |
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if __name__ == "__main__": |
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torch.set_float32_matmul_precision("high") |
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from jsonargparse.cli import CLI |
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CLI(main) |
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