import sys import time from pathlib import Path from typing import Any, Literal, Optional import lightning as L import torch import torch._dynamo.config import torch._inductor.config from lightning.fabric.plugins import BitsandbytesPrecision from lightning.fabric.strategies import FSDPStrategy # support running without installing as a package wd = Path(__file__).parent.parent.resolve() sys.path.append(str(wd)) from model import * from utils import * from tokenizer import * def multinomial_num_samples_1(probs: torch.Tensor) -> torch.Tensor: if torch._dynamo.is_compiling(): # Faster alternative to `torch.multinomial(probs, num_samples=1)` that is also CUDAGraph friendly distribution = torch.empty_like(probs).exponential_(1) return torch.argmax(probs / distribution, dim=-1, keepdim=True) return torch.multinomial(probs, num_samples=1) def sample(logits: torch.Tensor, temperature: float = 1.0, top_k: Optional[int] = None) -> torch.Tensor: logits = logits[0, -1] # optionally crop the logits to only the top k options if top_k is not None: v, i = torch.topk(logits, min(top_k, logits.size(-1))) # do not use `torch.where` as in nanogpt because it will repeat top-k collisions logits = torch.full_like(logits, float("-inf")).scatter_(-1, i, v) # optionally scale the logits and sample from a probability distribution if temperature > 0.0: probs = torch.nn.functional.softmax(logits / temperature, dim=-1) return multinomial_num_samples_1(probs) return torch.argmax(logits, dim=-1, keepdim=True) def next_token(model: GPT, input_pos: torch.Tensor, x: torch.Tensor, **kwargs: Any) -> torch.Tensor: logits = model(x, input_pos) next = sample(logits, **kwargs) return next.type_as(x) @torch.inference_mode() def generate( model: GPT, prompt: torch.Tensor, max_returned_tokens: int, *, temperature: float = 1.0, top_k: Optional[int] = None, eos_id: Optional[int] = None, ) -> torch.Tensor: """Takes a conditioning sequence (prompt) as input and continues to generate as many tokens as requested. The implementation of this function is modified from A. Karpathy's nanoGPT. Args: model: The model to use. prompt: Tensor of shape (T) with indices of the prompt sequence. max_returned_tokens: The maximum number of tokens to return (given plus generated). temperature: Scales the predicted logits by 1 / temperature. top_k: If specified, only sample among the tokens with the k highest probabilities. eos_id: If specified, stop generating any more token once the token is triggered. """ T = prompt.size(0) assert max_returned_tokens > T if model.max_seq_length < max_returned_tokens - 1: # rolling the kv cache based on the `input_pos` value would be necessary. However, doing so would introduce a # data dependency on the `input_pos` tensor and impact model compilation. Since this setting is uncommon, we do # not support it to avoid negatively impacting the overall speed raise NotImplementedError(f"max_seq_length {model.max_seq_length} needs to be >= {max_returned_tokens - 1}") device = prompt.device tokens = [prompt] input_pos = torch.tensor([T], device=device) token = next_token( model, torch.arange(0, T, device=device), prompt.view(1, -1), temperature=temperature, top_k=top_k ).clone() tokens.append(token) for _ in range(2, max_returned_tokens - T + 1): token = next_token(model, input_pos, token.view(1, -1), temperature=temperature, top_k=top_k).clone() tokens.append(token) if token == eos_id: break input_pos = input_pos.add_(1) return torch.cat(tokens) def main( prompt: str = "What food do llamas eat?", *, num_samples: int = 1, max_new_tokens: int = 50, top_k: Optional[int] = 200, temperature: float = 0.8, checkpoint_dir: Path = Path("checkpoints/stabilityai/stablelm-base-alpha-3b"), quantize: Optional[Literal["bnb.nf4", "bnb.nf4-dq", "bnb.fp4", "bnb.fp4-dq", "bnb.int8", "gptq.int4"]] = None, strategy: str = "auto", devices: int = 1, precision: Optional[str] = None, compile: bool = False, model_name: str = "pythia_160m_hf" ) -> None: """Generates text samples based on a pre-trained model and tokenizer. Args: prompt: The prompt string to use for generating the samples. num_samples: The number of text samples to generate. max_new_tokens: The number of generation steps to take. top_k: The number of top most probable tokens to consider in the sampling process. temperature: A value controlling the randomness of the sampling process. Higher values result in more random samples. checkpoint_dir: The checkpoint directory to load. quantize: Whether to quantize the model and using which method: - bnb.nf4, bnb.nf4-dq, bnb.fp4, bnb.fp4-dq: 4-bit quantization from bitsandbytes - bnb.int8: 8-bit quantization from bitsandbytes - gptq.int4: 4-bit quantization from GPTQ for more details, see https://github.com/Lightning-AI/lit-gpt/blob/main/tutorials/quantize.md strategy: Indicates the Fabric strategy setting to use. devices: How many devices to use. precision: Indicates the Fabric precision setting to use. compile: Whether to compile the model. """ precision = precision or get_default_supported_precision(training=False) plugins = None if quantize is not None: if devices > 1: raise NotImplementedError( "Quantization is currently not supported for multi-GPU training. Please set devices=1 when using the" " --quantize flag." ) if quantize.startswith("bnb."): if "mixed" in precision: raise ValueError("Quantization and mixed precision is not supported.") dtype = {"16-true": torch.float16, "bf16-true": torch.bfloat16, "32-true": torch.float32}[precision] plugins = BitsandbytesPrecision(quantize[4:], dtype) precision = None if strategy == "fsdp": strategy = FSDPStrategy(auto_wrap_policy={Block}, cpu_offload=False) fabric = L.Fabric(devices=devices, precision=precision, strategy=strategy, plugins=plugins) fabric.launch() check_valid_checkpoint_dir(checkpoint_dir, model_name) config = Config.from_json(checkpoint_dir / "lit_config.json") if quantize == "gptq.int4": model_file = "lit_model_gptq.4bit.pth" if not (checkpoint_dir / model_file).is_file(): raise ValueError("Please run `python quantize/gptq.py` first") else: if model_name == "pythia_160m_deduped_huggingface": model_file = "pythia_160m_deduped_hf.pth" elif model_name == "pythia_160m_deduped_custom": model_file = "pythia_160m_deduped_custom.pth" else: model_file = "lit_model.pth" checkpoint_path = checkpoint_dir / model_file tokenizer = Tokenizer(checkpoint_dir) encoded = tokenizer.encode(prompt, device=fabric.device) prompt_length = encoded.size(0) max_returned_tokens = prompt_length + max_new_tokens fabric.print(f"Loading model {str(checkpoint_path)!r} with {config.__dict__}", file=sys.stderr) t0 = time.perf_counter() with fabric.init_module(empty_init=True), gptq_quantization(quantize == "gptq.int4"): model = GPT(config) fabric.print(f"Time to instantiate model: {time.perf_counter() - t0:.02f} seconds.", file=sys.stderr) with fabric.init_tensor(): # set the max_seq_length to limit the memory usage to what we need model.max_seq_length = max_returned_tokens # enable the kv cache model.set_kv_cache(batch_size=1) model.eval() if compile: torch._dynamo.config.automatic_dynamic_shapes = True torch._inductor.config.triton.unique_kernel_names = True torch._inductor.config.coordinate_descent_tuning = True global next_token next_token = torch.compile(next_token, mode="reduce-overhead") model = fabric.setup_module(model) t0 = time.perf_counter() load_checkpoint(fabric, model, checkpoint_path) fabric.print(f"Time to load the model weights: {time.perf_counter() - t0:.02f} seconds.", file=sys.stderr) L.seed_everything(1234) print(f'num_samples is {num_samples}') output_msg_list = [] for i in range(num_samples): t0 = time.perf_counter() y = generate(model, encoded, max_returned_tokens, temperature=temperature, top_k=top_k) t = time.perf_counter() - t0 for block in model.transformer.h: block.attn.kv_cache.reset_parameters() output_msg = tokenizer.decode(y) tokens_generated = y.size(0) - prompt_length output_msg_list.append(output_msg) fabric.print( f"Time for inference {i + 1}: {t:.02f} sec total, {tokens_generated / t:.02f} tokens/sec", file=sys.stderr ) if fabric.device.type == "cuda": fabric.print(f"Memory used: {torch.cuda.max_memory_allocated() / 1e9:.02f} GB", file=sys.stderr) return output_msg_list if __name__ == "__main__": from jsonargparse import CLI torch.set_float32_matmul_precision("high") output_msg_list = CLI(main)