import dataclasses import importlib import os from abc import ABC, abstractmethod from typing import Any, Callable, Dict, List, Optional, Set, Tuple, Type, Union import torch from loguru import logger from aphrodite.common.sequence import (ExecuteModelRequest, IntermediateTensors, SamplerOutput) from aphrodite.common.utils import (enable_trace_function_call_for_thread, update_environment_variables) from aphrodite.distributed import (broadcast_tensor_dict, get_pp_group, get_tp_group) from aphrodite.lora.request import LoRARequest from aphrodite.platforms import current_platform from aphrodite.task_handler.model_runner_base import (ModelRunnerBase, ModelRunnerInputBase) class WorkerBase(ABC): """Worker interface that allows Aphrodite to cleanly separate implementations for different hardware. Also abstracts control plane communication, e.g., to communicate request metadata to other workers. """ @abstractmethod def init_device(self) -> None: """Initialize device state, such as loading the model or other on-device memory allocations. """ raise NotImplementedError @abstractmethod def determine_num_available_blocks(self) -> Tuple[int, int]: """Determine the number of available blocks for the GPU KV cache and swappable CPU KV cache. The implementation may run profiling or other heuristics to determine the size of caches. Returns a Tuple[num_gpu_blocks, num_cpu_blocks], where num_gpu_blocks are blocks that are "active" on the device and can be appended to. num_cpu_blocks refers to "swapped" blocks in CPU memory and cannot be appended to. """ raise NotImplementedError @abstractmethod def initialize_cache(self, num_gpu_blocks: int, num_cpu_blocks: int) -> None: """Initialize the KV cache with the given size in blocks. """ raise NotImplementedError @current_platform.inference_mode() def start_worker_execution_loop(self) -> None: """Execute model loop in parallel worker. You can stop the loop by executing a driver worker with an empty output. See `stop_remote_worker_execution_loop` for more details. """ while True: output = self.execute_model(execute_model_req=None) if output is None: return None @abstractmethod def execute_model( self, execute_model_req: Optional[ExecuteModelRequest] = None ) -> Optional[List[SamplerOutput]]: raise NotImplementedError @abstractmethod def get_cache_block_size_bytes(self) -> int: """Return the size of a single cache block, in bytes. Used in speculative decoding. """ raise NotImplementedError @abstractmethod def add_lora(self, lora_request: LoRARequest) -> bool: raise NotImplementedError @abstractmethod def remove_lora(self, lora_id: int) -> bool: raise NotImplementedError @abstractmethod def pin_lora(self, lora_id: int) -> bool: raise NotImplementedError @abstractmethod def list_loras(self) -> Set[int]: raise NotImplementedError class LoraNotSupportedWorkerBase(WorkerBase): """Partial implementation of WorkerBase that raises exceptions when LoRA methods are invoked. """ def add_lora(self, lora_request: LoRARequest) -> bool: raise ValueError(f"{type(self)} does not support LoRA") def remove_lora(self, lora_id: int) -> bool: raise ValueError(f"{type(self)} does not support LoRA") def pin_lora(self, lora_id: int) -> bool: return ValueError( f"{type(self)} does not support LoRA") # type: ignore def list_loras(self) -> Set[int]: raise ValueError(f"{type(self)} does not support LoRA") @dataclasses.dataclass(frozen=True) class WorkerInput: """Local inputs to each worker. May contain device-specific data. These fields should be broadcastable to other workers. """ num_seq_groups: Optional[int] = None blocks_to_swap_in: Optional[torch.Tensor] = None blocks_to_swap_out: Optional[torch.Tensor] = None blocks_to_copy: Optional[torch.Tensor] = None virtual_engine: int = 0 num_steps: int = 1 @classmethod def from_broadcasted_tensor_dict( cls: Type["WorkerInput"], tensor_dict: Dict[str, Any], ) -> "WorkerInput": """ Pop fields from the given tensor_dict and populate a new instance of WorkerInput. """ return cls( num_seq_groups=tensor_dict.pop("num_seq_groups"), blocks_to_swap_in=tensor_dict.pop("blocks_to_swap_in"), blocks_to_swap_out=tensor_dict.pop("blocks_to_swap_out"), blocks_to_copy=tensor_dict.pop("blocks_to_copy"), virtual_engine=tensor_dict["virtual_engine"], num_steps=tensor_dict.pop("num_steps"), ) def as_broadcastable_tensor_dict( self) -> Dict[str, Union[int, torch.Tensor]]: """ Extract broadcastable fields. """ tensor_dict = { "num_seq_groups": self.num_seq_groups, "blocks_to_swap_in": self.blocks_to_swap_in, "blocks_to_swap_out": self.blocks_to_swap_out, "blocks_to_copy": self.blocks_to_copy, "virtual_engine": self.virtual_engine, "num_steps": self.num_steps, } return tensor_dict class LocalOrDistributedWorkerBase(WorkerBase): """ Partial implementation of WorkerBase that has a default `execute_model` definition to perform metadata transfer between workers when in distributed mode. Subclasses of this interface should use model runners that inherit from ModelRunnerBase, and should only need to implement worker-local logic. If custom control plane logic is needed to transfer metadata, or if the model runner cannot inherit from ModelRunnerBase, use WorkerBase instead. """ is_driver_worker: bool model_runner: ModelRunnerBase @property @abstractmethod def do_metadata_broadcast(self) -> bool: """ Used by the default `execute_model` to check whether broadcast is needed to transfer request inputs from the driver worker to other workers in the TP group. If WorkerBase subclass only supports single-worker execution, then this method should return False. """ raise NotImplementedError @property @abstractmethod def kv_cache(self) -> Optional[List[List[torch.Tensor]]]: """ Gets the list of kv caches to pass to the worker's model runner. Each element in the list is a kv cache corresponding to a particular virtual engine (PP stream). Used by the default `execute_model`. If the worker's model runner does not follow the ModelRunnerBase interface, then inherit from WorkerBase instead. """ raise NotImplementedError @abstractmethod def prepare_worker_input( self, execute_model_req: ExecuteModelRequest) -> WorkerInput: """ Prepare the inputs to WorkerBase.execute_worker from an execution request. This method may move data to the worker's local device. It is not allowed to communicate with other workers or devices. """ raise NotImplementedError @abstractmethod def execute_worker(self, worker_input: WorkerInput) -> None: """ Process an execution request. """ raise NotImplementedError def _get_worker_input_from_broadcast( self) -> Optional[Tuple[ModelRunnerInputBase, WorkerInput]]: """ Get the worker input from the broadcasted tensor dict. """ assert self.do_metadata_broadcast assert not self.is_driver_worker broadcast_data = broadcast_tensor_dict(src=0) if not broadcast_data: return None worker_input = WorkerInput.from_broadcasted_tensor_dict(broadcast_data) model_input = ( self.model_runner.make_model_input_from_broadcasted_tensor_dict( broadcast_data)) return model_input, worker_input def _get_driver_input_and_broadcast( self, execute_model_req: ExecuteModelRequest ) -> Tuple[ModelRunnerInputBase, WorkerInput]: """ Get the driver input and broadcast it to other workers. """ assert self.is_driver_worker worker_input: WorkerInput = self.prepare_worker_input( execute_model_req=execute_model_req) model_input: ModelRunnerInputBase = ( self.model_runner.prepare_model_input( execute_model_req.seq_group_metadata_list, execute_model_req.virtual_engine, execute_model_req.finished_requests_ids)) if self.do_metadata_broadcast: broadcast_data = worker_input.as_broadcastable_tensor_dict() broadcast_data.update(model_input.as_broadcastable_tensor_dict()) broadcast_tensor_dict(broadcast_data, src=0) return model_input, worker_input def prepare_input( self, execute_model_req: Optional[ExecuteModelRequest] = None ) -> Optional[Tuple[ModelRunnerInputBase, WorkerInput]]: """ Prepare the inputs to ModelRunner and workers. """ if self.is_driver_worker: if execute_model_req is None: if self.do_metadata_broadcast: # This signals that there's no more requests to process for # now. All workers are running infinite loop with # broadcast_tensor_dict, and it stops the loop when the # driver broadcasts an empty input. Send an empty input to # notify all other workers to stop their execution loop. broadcast_tensor_dict({}, src=0) return None return self._get_driver_input_and_broadcast(execute_model_req) else: return self._get_worker_input_from_broadcast() def execute_model( self, execute_model_req: Optional[ExecuteModelRequest] = None ) -> Optional[List[SamplerOutput]]: """Executes at least one model step on the given sequences, unless no sequences are provided.""" inputs = self.prepare_input(execute_model_req) if inputs is None: return None model_input, worker_input = inputs num_steps = worker_input.num_steps self.execute_worker(worker_input) # If there is no input, we don't need to execute the model. if worker_input.num_seq_groups == 0: return [] intermediate_tensors = None if not get_pp_group().is_first_rank: intermediate_tensors = IntermediateTensors( get_pp_group().recv_tensor_dict( all_gather_group=get_tp_group())) output = self.model_runner.execute_model( model_input, self.kv_cache[worker_input.virtual_engine] if self.kv_cache is not None else None, intermediate_tensors, num_steps) if not get_pp_group().is_last_rank: # output is IntermediateTensors get_pp_group().send_tensor_dict(output.tensors, all_gather_group=get_tp_group()) return [None] # output is List[SamplerOutput] return output def _execute_model_spmd( self, execute_model_req: ExecuteModelRequest, intermediate_tensors: Optional[IntermediateTensors] = None ) -> Optional[List[SamplerOutput]]: """ Execute model in Single Program Multiple Data (SPMD) fashion. All workers take the same request, prepare the input and execute the model. """ assert execute_model_req is not None, ( "_execute_model_spmd() requires each worker to take in an " "ExecuteModelRequest") worker_input: WorkerInput = self.prepare_worker_input( execute_model_req=execute_model_req) model_input: ModelRunnerInputBase = ( self.model_runner.prepare_model_input( execute_model_req.seq_group_metadata_list)) self.execute_worker(worker_input) # If there is no input, we don't need to execute the model. if worker_input.num_seq_groups == 0: return [] return self.model_runner.execute_model( model_input, self.kv_cache[worker_input.virtual_engine] if self.kv_cache is not None else None, intermediate_tensors) class WorkerWrapperBase: """ The whole point of this class is to lazily initialize the worker. We first instantiate the WorkerWrapper, which remembers the worker module and class name. Then, when we call `update_environment_variables`, and the real initialization happens in `init_worker`. If worker_class_fn is specified, it will be executed to get the worker class. Otherwise, the worker class will be obtained by dynamically importing it using worker_module_name and worker_class_name. """ def __init__( self, worker_module_name: str, worker_class_name: str, trust_remote_code: bool = False, worker_class_fn: Optional[Callable[[], Type[WorkerBase]]] = None) -> None: self.worker_module_name = worker_module_name self.worker_class_name = worker_class_name self.worker_class_fn = worker_class_fn self.worker: Optional[WorkerBase] = None if trust_remote_code: # note: lazy import to avoid importing torch before initializing from aphrodite.common.utils import init_cached_hf_modules init_cached_hf_modules() @staticmethod def update_environment_variables(envs: Dict[str, str]) -> None: key = 'CUDA_VISIBLE_DEVICES' if key in envs and key in os.environ: # overwriting CUDA_VISIBLE_DEVICES is desired behavior # suppress the warning in `update_environment_variables` del os.environ[key] update_environment_variables(envs) def init_worker(self, *args, **kwargs): """ Here we inject some common logic before initializing the worker. Arguments are passed to the worker class constructor. """ enable_trace_function_call_for_thread() # see https://github.com/NVIDIA/nccl/issues/1234 os.environ['NCCL_CUMEM_ENABLE'] = '0' from aphrodite.plugins import load_general_plugins load_general_plugins() if self.worker_class_fn: worker_class = self.worker_class_fn() else: mod = importlib.import_module(self.worker_module_name) worker_class = getattr(mod, self.worker_class_name) self.worker = worker_class(*args, **kwargs) assert self.worker is not None def execute_method(self, method, *args, **kwargs): try: target = self if self.worker is None else self.worker executor = getattr(target, method) return executor(*args, **kwargs) except Exception as e: # if the driver worker also execute methods, # exceptions in the rest worker may cause deadlock in rpc like ray # print the error and inform the user to solve the error msg = (f"Error executing method {method}. " "This might cause deadlock in distributed execution.") logger.exception(msg) raise e