# SPDX-FileCopyrightText: Copyright (c) 2025-2026 NVIDIA CORPORATION & AFFILIATES. All rights reserved. # SPDX-License-Identifier: Apache-2.0 import argparse import asyncio import logging import os import signal import sys from io import BytesIO from queue import Queue from typing import AsyncIterator, Optional, Tuple import av import numpy as np import torch import uvloop from vllm.engine.arg_utils import AsyncEngineArgs from vllm.utils.argparse_utils import FlexibleArgumentParser import dynamo.nixl_connect as connect from dynamo.runtime import Client, DistributedRuntime, dynamo_worker from dynamo.runtime.logging import configure_dynamo_logging sys.path.append(os.path.join(os.path.dirname(os.path.abspath(__file__)), "..")) from utils.args import Config, base_parse_args, parse_endpoint from utils.protocol import MyRequestOutput, vLLMMultimodalRequest from utils.video_utils import ( calculate_frame_sampling_indices, get_video_metadata, load_video_content, open_video_container, prepare_tensor_for_rdma, read_video_pyav, resize_video_frames, ) configure_dynamo_logging() logger = logging.getLogger(__name__) try: import cupy as array_module if not array_module.cuda.is_available(): raise ImportError("CUDA is not available.") DEVICE = "cuda" logger.info("Using cupy for array operations (GPU mode).") except ImportError as e: logger.warning(f"Failed to import cupy, falling back to numpy: {e}.") import numpy as array_module DEVICE = "cpu" CACHE_SIZE_MAXIMUM = 8 class VllmEncodeWorker: def __init__( self, args: argparse.Namespace, engine_args: AsyncEngineArgs, pd_worker_client: Client, ) -> None: self.pd_worker_client = pd_worker_client self.engine_args = engine_args self.model = self.engine_args.model self.min_workers = 1 # Video processing parameters self.num_frames_to_sample = args.num_frames_to_sample self.frame_height = 336 self.frame_width = 336 self.frame_channels = 3 self._video_content_cache: dict[str, BytesIO] = {} self._cache_queue: Queue[str] = Queue(maxsize=CACHE_SIZE_MAXIMUM) self._http_timeout = 60.0 def cleanup(self): pass async def generate( self, request: vLLMMultimodalRequest ) -> AsyncIterator[MyRequestOutput]: logger.debug(f"Got raw request: {request}") if not isinstance(request, vLLMMultimodalRequest): if isinstance(request, str): request = vLLMMultimodalRequest.model_validate_json(request) else: request = vLLMMultimodalRequest.model_validate(request) logger.debug(f"Received encode request: {{ id: {request.request_id} }}.") request_id = request.request_id video_url = request.multimodal_input.video_url if video_url is None: raise ValueError("Video URL is required.") container: Optional[av.container.InputContainer] = None try: video_content_stream = await load_video_content( video_url, self._video_content_cache, self._cache_queue, self._http_timeout, ) # Open video container using utility function container = await open_video_container(video_content_stream, video_url) if not container or not container.streams.video: logger.error(f"No video stream found in {video_url}.") raise ValueError(f"No video stream in {video_url}.") # Get video metadata using utility function total_frames, duration_sec = get_video_metadata(container) # Calculate frame sampling indices using utility function indices = calculate_frame_sampling_indices( total_frames, self.num_frames_to_sample, duration_sec, video_url ) if not container: raise ValueError(f"Container is None for {video_url}") # Decode video frames clip_np: np.ndarray = await read_video_pyav(container, indices) if clip_np.size == 0: raise ValueError( f"Failed to extract any video frames from {video_url} for indices {indices.tolist()}. Clip is empty." ) logger.debug( f"Successfully extracted {len(clip_np) if clip_np.ndim > 1 and clip_np.shape[0] > 0 else 0} frames for {video_url} with original shape {clip_np.shape}." ) # Convert the NumPy array from the video decoder into a PyTorch tensor. # This is a required step to use PyTorch functions for GPU-accelerated image processing. frames_tensor_orig_res = torch.from_numpy(clip_np) # Shape: (T, H, W, C) # Resize frames using utility function resized_frames_tensor_hwc = resize_video_frames( frames_tensor_orig_res, self.frame_height, self.frame_width ) # Prepare tensor for RDMA using utility function tensor_for_descriptor = prepare_tensor_for_rdma( resized_frames_tensor_hwc, request_id ) request.embeddings_shape = tuple(tensor_for_descriptor.shape) descriptor = connect.Descriptor(tensor_for_descriptor) with await self._connector.create_readable(descriptor) as readable: request.serialized_request = readable.metadata() # Clear the image URL as hint that the image is passed as embeddings. request.multimodal_input.video_url = None logger.debug(f"Request: {request.model_dump_json()}") # Get the response generator response_generator = await self.pd_worker_client.round_robin( request.model_dump_json() ) await readable.wait_for_completion() async for response in response_generator: output = MyRequestOutput.model_validate_json(response.data()) yield MyRequestOutput( request_id=output.request_id, prompt=output.prompt, prompt_token_ids=output.prompt_token_ids, prompt_logprobs=output.prompt_logprobs, outputs=output.outputs, finished=output.finished, ).model_dump_json() except ( FileNotFoundError, av.FFmpegError, ValueError, ) as e: logger.error( f"Error processing request {request_id} ({video_url[:100]}...): {type(e).__name__} - {e}" ) raise # Re-raise to be handled by the service framework except Exception as e: logger.exception( f"Unexpected error processing request {request_id} ({video_url[:100]}...): {e}" ) raise finally: if container: await asyncio.to_thread(container.close) async def async_init(self, runtime: DistributedRuntime): logger.info("Startup started.") # Create and initialize a dynamo connector for this worker. # We'll needs this to move data between this worker and remote workers efficiently. self._connector = connect.Connector() logger.info("Startup completed.") @classmethod def parse_args(cls) -> Tuple[argparse.Namespace, Config]: DYN_NAMESPACE = os.environ.get("DYN_NAMESPACE", "dynamo") DEFAULT_ENDPOINT = f"dyn://{DYN_NAMESPACE}.encoder.generate" DEFAULT_DOWNSTREAM_ENDPOINT = f"dyn://{DYN_NAMESPACE}.llm.generate" parser = FlexibleArgumentParser( description="vLLM based encoder for Dynamo LLM." ) parser.add_argument( "--endpoint", type=str, default=DEFAULT_ENDPOINT, help=f"Dynamo endpoint string in 'dyn://namespace.component.endpoint' format. Default: '{DEFAULT_ENDPOINT}'", ) parser.add_argument( "--downstream-endpoint", type=str, default=DEFAULT_DOWNSTREAM_ENDPOINT, help=f"The endpoint string of the downstream LLM in 'dyn://namespace.component.endpoint' format. Default: '{DEFAULT_DOWNSTREAM_ENDPOINT}'", ) parser.add_argument( "--num-frames-to-sample", type=int, default=8, help="Number of frames to sample from the video. Default: 8", ) args, config = base_parse_args(parser) return args, config async def graceful_shutdown(runtime): """ By calling `runtime.shutdown()`, the endpoints will immediately be unavailable. However, in-flight requests will still be processed until they are finished. After all in-flight requests are finished, the `serve_endpoint` functions will return and the engine will be shutdown by Python's garbage collector. """ logging.info("Received shutdown signal, shutting down DistributedRuntime") runtime.shutdown() logging.info("DistributedRuntime shutdown complete") @dynamo_worker() async def worker(runtime: DistributedRuntime): # Runtime setup # Set up signal handler for graceful shutdown loop = asyncio.get_running_loop() def signal_handler(): asyncio.create_task(graceful_shutdown(runtime)) for sig in (signal.SIGTERM, signal.SIGINT): loop.add_signal_handler(sig, signal_handler) logging.info("Signal handlers set up for graceful shutdown") # worker setup args, config = VllmEncodeWorker.parse_args() await init(runtime, args, config) async def init(runtime: DistributedRuntime, args: argparse.Namespace, config: Config): """ Instantiate and serve """ generate_endpoint = runtime.endpoint( f"{config.namespace}.{config.component}.{config.endpoint}" ) parsed_namespace, parsed_component_name, parsed_endpoint_name = parse_endpoint( args.downstream_endpoint ) pd_worker_client = await runtime.endpoint( f"{parsed_namespace}.{parsed_component_name}.{parsed_endpoint_name}" ).client() handler = VllmEncodeWorker(args, config.engine_args, pd_worker_client) await handler.async_init(runtime) logger.info("Waiting for PD Worker Instances ...") await pd_worker_client.wait_for_instances() logger.info(f"Starting to serve the {args.endpoint} endpoint...") try: await asyncio.gather( generate_endpoint.serve_endpoint( handler.generate, metrics_labels=[("model", config.model)] ), ) except Exception as e: logger.error(f"Failed to serve endpoints: {e}") raise finally: handler.cleanup() if __name__ == "__main__": uvloop.install() asyncio.run(worker())