from contextlib import contextmanager from typing import (Any, ClassVar, Dict, List, Optional, Sequence, Union, cast, overload) from tqdm import tqdm from aphrodite.common.outputs import EmbeddingRequestOutput, RequestOutput from aphrodite.common.pooling_params import PoolingParams from aphrodite.common.sampling_params import RequestOutputKind, SamplingParams from aphrodite.common.utils import Counter, deprecate_kwargs, is_list_of from aphrodite.endpoints.chat_utils import (ChatCompletionMessageParam, apply_hf_chat_template, apply_mistral_chat_template, parse_chat_messages) from aphrodite.engine.aphrodite_engine import AphroditeEngine from aphrodite.engine.args_tools import EngineArgs from aphrodite.inputs import PromptType, TextPrompt, TokensPrompt from aphrodite.inputs.parse import parse_and_batch_prompt from aphrodite.lora.request import LoRARequest from aphrodite.modeling.guided_decoding import ( GuidedDecodingRequest, get_local_guided_decoding_logits_processor) from aphrodite.modeling.guided_decoding.guided_fields import LLMGuidedOptions from aphrodite.prompt_adapter.request import PromptAdapterRequest from aphrodite.transformers_utils.tokenizer import (AnyTokenizer, MistralTokenizer, get_cached_tokenizer) from aphrodite.transformers_utils.tokenizer_group import TokenizerGroup class LLM: """An LLM for generating texts from given prompts and sampling parameters. This class includes a tokenizer, a language model (possibly distributed across multiple GPUs), and GPU memory space allocated for intermediate states (aka KV cache). Given a batch of prompts and sampling parameters, this class generates texts from the model, using an intelligent batching mechanism and efficient memory management. Args: model: The name or path of a HuggingFace Transformers model. tokenizer: The name or path of a HuggingFace Transformers tokenizer. tokenizer_mode: The tokenizer mode. "auto" will use the fast tokenizer if available, and "slow" will always use the slow tokenizer. skip_tokenizer_init: If true, skip initialization of tokenizer and detokenizer. Expect valid prompt_token_ids and None for prompt from the input. trust_remote_code: Trust remote code (e.g., from HuggingFace) when downloading the model and tokenizer. tensor_parallel_size: The number of GPUs to use for distributed execution with tensor parallelism. dtype: The data type for the model weights and activations. Currently, we support `float32`, `float16`, and `bfloat16`. If `auto`, we use the `torch_dtype` attribute specified in the model config file. However, if the `torch_dtype` in the config is `float32`, we will use `float16` instead. quantization: The method used to quantize the model weights. Currently, we support "awq", "gptq", and "fp8" (experimental). If None, we first check the `quantization_config` attribute in the model config file. If that is None, we assume the model weights are not quantized and use `dtype` to determine the data type of the weights. revision: The specific model version to use. It can be a branch name, a tag name, or a commit id. tokenizer_revision: The specific tokenizer version to use. It can be a branch name, a tag name, or a commit id. seed: The seed to initialize the random number generator for sampling. gpu_memory_utilization: The ratio (between 0 and 1) of GPU memory to reserve for the model weights, activations, and KV cache. Higher values will increase the KV cache size and thus improve the model's throughput. However, if the value is too high, it may cause out-of- memory (OOM) errors. swap_space: The size (GiB) of CPU memory per GPU to use as swap space. This can be used for temporarily storing the states of the requests when their `best_of` sampling parameters are larger than 1. If all requests will have `best_of=1`, you can safely set this to 0. Otherwise, too small values may cause out-of-memory (OOM) errors. cpu_offload_gb: The size (GiB) of CPU memory to use for offloading the model weights. This virtually increases the GPU memory space you can use to hold the model weights, at the cost of CPU-GPU data transfer for every forward pass. enforce_eager: Whether to enforce eager execution. If True, we will disable CUDA graph and always execute the model in eager mode. If False, we will use CUDA graph and eager execution in hybrid. max_context_len_to_capture: Maximum context len covered by CUDA graphs. When a sequence has context length larger than this, we fall back to eager mode (DEPRECATED. Use `max_seq_len_to_capture` instead). max_seq_len_to_capture: Maximum sequence len covered by CUDA graphs. When a sequence has context length larger than this, we fall back to eager mode. Additionally for encoder-decoder models, if the sequence length of the encoder input is larger than this, we fall back to the eager mode. disable_custom_all_reduce: See ParallelConfig **kwargs: Arguments for :class:`~aphrodite.EngineArgs`. (See :ref:`engine_args`) Note: This class is intended to be used for offline inference. For online serving, use the :class:`~aphrodite.AsyncAphrodite` class instead. """ DEPRECATE_LEGACY: ClassVar[bool] = False """A flag to toggle whether to deprecate the legacy generate/encode API.""" @classmethod @contextmanager def deprecate_legacy_api(cls): cls.DEPRECATE_LEGACY = True yield cls.DEPRECATE_LEGACY = False def __init__( self, model: str, tokenizer: Optional[str] = None, tokenizer_mode: str = "auto", skip_tokenizer_init: bool = False, trust_remote_code: bool = False, tensor_parallel_size: int = 1, dtype: str = "auto", quantization: Optional[str] = None, revision: Optional[str] = None, tokenizer_revision: Optional[str] = None, seed: int = 0, gpu_memory_utilization: float = 0.9, swap_space: float = 4, cpu_offload_gb: float = 0, enforce_eager: Optional[bool] = None, max_context_len_to_capture: Optional[int] = None, max_seq_len_to_capture: int = 8192, disable_custom_all_reduce: bool = False, disable_async_output_proc: bool = False, **kwargs, ) -> None: ''' LLM constructor. Note: if enforce_eager is unset (enforce_eager is None) it defaults to False. ''' if "disable_log_stats" not in kwargs: kwargs["disable_log_stats"] = True removed_vision_keys = ( "image_token_id", "image_feature_size", "image_input_shape", "image_input_type", ) if any(k in kwargs for k in removed_vision_keys): raise TypeError( "There is no need to pass vision-related arguments anymore.") engine_args = EngineArgs( model=model, tokenizer=tokenizer, tokenizer_mode=tokenizer_mode, skip_tokenizer_init=skip_tokenizer_init, trust_remote_code=trust_remote_code, tensor_parallel_size=tensor_parallel_size, dtype=dtype, quantization=quantization, revision=revision, tokenizer_revision=tokenizer_revision, seed=seed, gpu_memory_utilization=gpu_memory_utilization, swap_space=swap_space, cpu_offload_gb=cpu_offload_gb, enforce_eager=enforce_eager, max_context_len_to_capture=max_context_len_to_capture, max_seq_len_to_capture=max_seq_len_to_capture, disable_custom_all_reduce=disable_custom_all_reduce, disable_async_output_proc=disable_async_output_proc, **kwargs, ) self.llm_engine = AphroditeEngine.from_engine_args(engine_args) self.request_counter = Counter() def get_tokenizer(self) -> AnyTokenizer: return self.llm_engine.get_tokenizer_group(TokenizerGroup).tokenizer def set_tokenizer(self, tokenizer: AnyTokenizer) -> None: tokenizer_group = self.llm_engine.get_tokenizer_group(TokenizerGroup) # While CachedTokenizer is dynamic, have no choice but # compare class name. Misjudgment will arise from # user-defined tokenizer started with 'Cached' if tokenizer.__class__.__name__.startswith("Cached"): tokenizer_group.tokenizer = tokenizer else: tokenizer_group.tokenizer = get_cached_tokenizer(tokenizer) @overload # LEGACY: single (prompt + optional token ids) def generate( self, prompts: str, sampling_params: Optional[Union[SamplingParams, List[SamplingParams]]] = None, prompt_token_ids: Optional[List[int]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[RequestOutput]: ... @overload # LEGACY: multi (prompt + optional token ids) def generate( self, prompts: List[str], sampling_params: Optional[Union[SamplingParams, List[SamplingParams]]] = None, prompt_token_ids: Optional[List[List[int]]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[RequestOutput]: ... @overload # LEGACY: single (token ids + optional prompt) def generate( self, prompts: Optional[str] = None, sampling_params: Optional[Union[SamplingParams, List[SamplingParams]]] = None, *, prompt_token_ids: List[int], use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[RequestOutput]: ... @overload # LEGACY: multi (token ids + optional prompt) def generate( self, prompts: Optional[List[str]] = None, sampling_params: Optional[Union[SamplingParams, List[SamplingParams]]] = None, *, prompt_token_ids: List[List[int]], use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[RequestOutput]: ... @overload # LEGACY: single or multi token ids [pos-only] def generate( self, prompts: None, sampling_params: None, prompt_token_ids: Union[List[int], List[List[int]]], use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[RequestOutput]: ... @overload def generate( self, prompts: Union[PromptType, Sequence[PromptType]], /, *, sampling_params: Optional[Union[SamplingParams, Sequence[SamplingParams]]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[RequestOutput]: ... @deprecate_kwargs( "prompts", "prompt_token_ids", is_deprecated=lambda: LLM.DEPRECATE_LEGACY, additional_message="Please use the 'inputs' parameter instead.", ) def generate( self, prompts: Union[Union[PromptType, Sequence[PromptType]], Optional[Union[str, List[str]]]] = None, sampling_params: Optional[Union[SamplingParams, Sequence[SamplingParams]]] = None, prompt_token_ids: Optional[Union[List[int], List[List[int]]]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, prompt_adapter_request: Optional[PromptAdapterRequest] = None, guided_options_request: Optional[Union[LLMGuidedOptions, GuidedDecodingRequest]] = None ) -> List[RequestOutput]: """Generates the completions for the input prompts. This class automatically batches the given prompts, considering the memory constraint. For the best performance, put all of your prompts into a single list and pass it to this method. Args: prompts: The prompts to the LLM. You may pass a sequence of prompts for batch inference. See :class:`~aphrodite.inputs.PromptType` for more details about the format of each prompts. sampling_params: The sampling parameters for text generation. If None, we use the default sampling parameters. When it is a single value, it is applied to every prompt. When it is a list, the list must have the same length as the prompts and it is paired one by one with the prompt. use_tqdm: Whether to use tqdm to display the progress bar. lora_request: LoRA request to use for generation, if any. prompt_adapter_request: Prompt Adapter request to use for generation, if any. Returns: A list of ``RequestOutput`` objects containing the generated completions in the same order as the input prompts. Note: Using ``prompts`` and ``prompt_token_ids`` as keyword parameters is considered legacy and may be deprecated in the future. You should instead pass them via the ``inputs`` parameter. """ if self.llm_engine.model_config.embedding_mode: raise ValueError( "LLM.generate() is only supported for (conditional) generation " "models (XForCausalLM, XForConditionalGeneration).") if prompt_token_ids is not None: parsed_prompts = self._convert_v1_inputs( prompts=cast(Optional[Union[str, List[str]]], prompts), prompt_token_ids=prompt_token_ids, ) else: parsed_prompts = cast(Union[PromptType, Sequence[PromptType]], prompts) if isinstance(guided_options_request, dict): if len(guided_options_request) > 1: raise ValueError( "You can only use one guided decoding but multiple is " f"specified: {guided_options_request}") guided_options_request = GuidedDecodingRequest( **guided_options_request) if sampling_params is None: # Use default sampling params. sampling_params = SamplingParams() self._validate_and_add_requests( prompts=parsed_prompts, params=sampling_params, lora_request=lora_request, prompt_adapter_request=prompt_adapter_request, guided_options=guided_options_request) outputs = self._run_engine(use_tqdm=use_tqdm) return AphroditeEngine.validate_outputs(outputs, RequestOutput) def chat( self, messages: List[ChatCompletionMessageParam], sampling_params: Optional[Union[SamplingParams, List[SamplingParams]]] = None, use_tqdm: bool = True, lora_request: Optional[LoRARequest] = None, chat_template: Optional[str] = None, add_generation_prompt: bool = True, tools: Optional[List[Dict[str, Any]]] = None, ) -> List[RequestOutput]: """ Generate responses for a chat conversation. The chat conversation is converted into a text prompt using the tokenizer and calls the :meth:`generate` method to generate the responses. Multi-modal inputs can be passed in the same way you would pass them to the OpenAI API. Args: messages: A single conversation represented as a list of messages. Each message is a dictionary with 'role' and 'content' keys. sampling_params: The sampling parameters for text generation. If None, we use the default sampling parameters. When it is a single value, it is applied to every prompt. When it is a list, the list must have the same length as the prompts and it is paired one by one with the prompt. use_tqdm: Whether to use tqdm to display the progress bar. lora_request: LoRA request to use for generation, if any. chat_template: The template to use for structuring the chat. If not provided, the model's default chat template will be used. add_generation_prompt: If True, adds a generation template to each message. Returns: A list of ``RequestOutput`` objects containing the generated responses in the same order as the input messages. """ tokenizer = self.get_tokenizer() model_config = self.llm_engine.get_model_config() conversation, mm_data = parse_chat_messages(messages, model_config, tokenizer) prompt_data: Union[str, List[int]] if isinstance(tokenizer, MistralTokenizer): prompt_data = apply_mistral_chat_template( tokenizer, messages=messages, chat_template=chat_template, add_generation_prompt=add_generation_prompt, tools=tools, ) else: prompt_data = apply_hf_chat_template( tokenizer, conversation=conversation, chat_template=chat_template, add_generation_prompt=add_generation_prompt, tools=tools, ) prompt: PromptType if is_list_of(prompt_data, int): prompt = TokensPrompt(prompt_token_ids=prompt_data) else: prompt = TextPrompt(prompt=prompt_data) if mm_data is not None: prompt["multi_modal_data"] = mm_data return self.generate( prompt, sampling_params=sampling_params, use_tqdm=use_tqdm, lora_request=lora_request, ) @overload # LEGACY: single (prompt + optional token ids) def encode( self, prompts: str, pooling_params: Optional[Union[PoolingParams, Sequence[PoolingParams]]] = None, prompt_token_ids: Optional[List[int]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[EmbeddingRequestOutput]: ... @overload # LEGACY: multi (prompt + optional token ids) def encode( self, prompts: List[str], pooling_params: Optional[Union[PoolingParams, Sequence[PoolingParams]]] = None, prompt_token_ids: Optional[List[List[int]]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[EmbeddingRequestOutput]: ... @overload # LEGACY: single (token ids + optional prompt) def encode( self, prompts: Optional[str] = None, pooling_params: Optional[Union[PoolingParams, Sequence[PoolingParams]]] = None, *, prompt_token_ids: List[int], use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[EmbeddingRequestOutput]: ... @overload # LEGACY: multi (token ids + optional prompt) def encode( self, prompts: Optional[List[str]] = None, pooling_params: Optional[Union[PoolingParams, Sequence[PoolingParams]]] = None, *, prompt_token_ids: List[List[int]], use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[EmbeddingRequestOutput]: ... @overload # LEGACY: single or multi token ids [pos-only] def encode( self, prompts: None, pooling_params: None, prompt_token_ids: Union[List[int], List[List[int]]], use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[EmbeddingRequestOutput]: ... @overload def encode( self, prompts: Union[PromptType, Sequence[PromptType]], /, *, pooling_params: Optional[Union[PoolingParams, Sequence[PoolingParams]]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, ) -> List[EmbeddingRequestOutput]: ... @deprecate_kwargs( "prompts", "prompt_token_ids", is_deprecated=lambda: LLM.DEPRECATE_LEGACY, additional_message="Please use the 'inputs' parameter instead.", ) def encode( self, prompts: Union[Union[PromptType, Sequence[PromptType]], Optional[Union[str, List[str]]]] = None, pooling_params: Optional[Union[PoolingParams, Sequence[PoolingParams]]] = None, prompt_token_ids: Optional[Union[List[int], List[List[int]]]] = None, use_tqdm: bool = True, lora_request: Optional[Union[List[LoRARequest], LoRARequest]] = None, prompt_adapter_request: Optional[PromptAdapterRequest] = None, ) -> List[EmbeddingRequestOutput]: """Generates the completions for the input prompts. This class automatically batches the given prompts, considering the memory constraint. For the best performance, put all of your prompts into a single list and pass it to this method. Args: prompts: The prompts to the LLM. You may pass a sequence of prompts for batch inference. See :class:`~aphrodite.inputs.PromptType` for more details about the format of each prompts. pooling_params: The pooling parameters for pooling. If None, we use the default pooling parameters. use_tqdm: Whether to use tqdm to display the progress bar. lora_request: LoRA request to use for generation, if any. prompt_adapter_request: Prompt Adapter request to use for generation, if any. Returns: A list of `EmbeddingRequestOutput` objects containing the generated embeddings in the same order as the input prompts. Note: Using ``prompts`` and ``prompt_token_ids`` as keyword parameters is considered legacy and may be deprecated in the future. You should instead pass them via the ``inputs`` parameter. """ if not self.llm_engine.model_config.embedding_mode: raise ValueError( "LLM.encode() is only supported for embedding models (XModel)." ) if prompt_token_ids is not None: parsed_prompts = self._convert_v1_inputs( prompts=cast(Optional[Union[str, List[str]]], prompts), prompt_token_ids=prompt_token_ids, ) else: parsed_prompts = cast(Union[PromptType, Sequence[PromptType]], prompts) if pooling_params is None: # Use default pooling params. pooling_params = PoolingParams() self._validate_and_add_requests( prompts=parsed_prompts, params=pooling_params, lora_request=lora_request, prompt_adapter_request=prompt_adapter_request, ) outputs = self._run_engine(use_tqdm=use_tqdm) return AphroditeEngine.validate_outputs(outputs, EmbeddingRequestOutput) # LEGACY def _convert_v1_inputs( self, prompts: Optional[Union[str, List[str]]], prompt_token_ids: Optional[Union[List[int], List[List[int]]]], ): # skip_tokenizer_init is now checked in engine if prompts is not None: prompts = [p["content"] for p in parse_and_batch_prompt(prompts)] if prompt_token_ids is not None: prompt_token_ids = [ p["content"] for p in parse_and_batch_prompt(prompt_token_ids) ] num_requests = None if prompts is not None: num_requests = len(prompts) if prompt_token_ids is not None: if (num_requests is not None and num_requests != len(prompt_token_ids)): raise ValueError("The lengths of prompts and prompt_token_ids " "must be the same.") num_requests = len(prompt_token_ids) if num_requests is None: raise ValueError("Either prompts or prompt_token_ids must be " "provided.") parsed_prompts: List[PromptType] = [] for i in range(num_requests): item: PromptType if prompts is not None: item = TextPrompt(prompt=prompts[i]) elif prompt_token_ids is not None: item = TokensPrompt(prompt_token_ids=prompt_token_ids[i]) else: raise AssertionError parsed_prompts.append(item) return parsed_prompts def _validate_and_add_requests( self, prompts: Union[PromptType, Sequence[PromptType]], params: Union[SamplingParams, Sequence[SamplingParams], PoolingParams, Sequence[PoolingParams]], lora_request: Optional[Union[Sequence[LoRARequest], LoRARequest]], prompt_adapter_request: Optional[PromptAdapterRequest], guided_options: Optional[GuidedDecodingRequest] = None, ) -> None: if isinstance(prompts, (str, dict)): # Convert a single prompt to a list. prompts = [prompts] num_requests = len(prompts) if isinstance(params, list) and len(params) != num_requests: raise ValueError("The lengths of prompts and params " "must be the same.") if isinstance(lora_request, list) and len(lora_request) != num_requests: raise ValueError("The lengths of prompts and lora_request " "must be the same.") for sp in params if isinstance(params, list) else (params, ): if isinstance(sp, SamplingParams): self._add_guided_processor(sp, guided_options) # We only care about the final output sp.output_kind = RequestOutputKind.FINAL_ONLY # Add requests to the engine. for i, prompt in enumerate(prompts): self._add_request( prompt, params[i] if isinstance(params, Sequence) else params, lora_request=lora_request[i] if isinstance( lora_request, Sequence) else lora_request, prompt_adapter_request=prompt_adapter_request, ) def _add_request( self, prompt: PromptType, params: Union[SamplingParams, PoolingParams], lora_request: Optional[LoRARequest] = None, prompt_adapter_request: Optional[PromptAdapterRequest] = None, ) -> None: request_id = str(next(self.request_counter)) self.llm_engine.add_request( request_id, prompt, params, lora_request=lora_request, prompt_adapter_request=prompt_adapter_request, ) def _add_guided_processor( self, params: SamplingParams, guided_options: Optional[GuidedDecodingRequest] = None): if guided_options: if guided_options.guided_decoding_backend is None: decoding_config = self.llm_engine.get_decoding_config() guided_options.guided_decoding_backend = ( decoding_config.guided_decoding_backend) guided_logits_processor = get_local_guided_decoding_logits_processor( #noqa guided_options.guided_decoding_backend, guided_options, self.get_tokenizer()) if guided_logits_processor: if params.logits_processors is None: params.logits_processors = [] params.logits_processors.append(guided_logits_processor) return params def _run_engine( self, *, use_tqdm: bool ) -> List[Union[RequestOutput, EmbeddingRequestOutput]]: # Initialize tqdm. if use_tqdm: num_requests = self.llm_engine.get_num_unfinished_requests() pbar = tqdm( total=num_requests, desc="Processed prompts", dynamic_ncols=True, postfix=(f"est. speed input: {0:.2f} toks/s, " f"output: {0:.2f} toks/s"), ) # Run the engine. outputs: List[Union[RequestOutput, EmbeddingRequestOutput]] = [] total_in_toks = 0 total_out_toks = 0 while self.llm_engine.has_unfinished_requests(): step_outputs = self.llm_engine.step() for output in step_outputs: if output.finished: outputs.append(output) if use_tqdm: if isinstance(output, RequestOutput): # Calculate tokens only for RequestOutput assert output.prompt_token_ids is not None total_in_toks += len(output.prompt_token_ids) in_spd = total_in_toks / pbar.format_dict["elapsed"] total_out_toks += sum( len(stp.token_ids) for stp in output.outputs) out_spd = (total_out_toks / pbar.format_dict["elapsed"]) pbar.postfix = ( f"est. speed input: {in_spd:.2f} toks/s, " f"output: {out_spd:.2f} toks/s") pbar.update(1) if use_tqdm: pbar.close() # Sort the outputs by request ID. # This is necessary because some requests may be finished earlier than # its previous requests. return sorted(outputs, key=lambda x: int(x.request_id)) def _is_encoder_decoder_model(self): return self.llm_engine.is_encoder_decoder_model() def _is_embedding_model(self): return self.llm_engine.is_embedding_model()