ray_gpu_executor.py

import asyncio
import os
from collections import defaultdict
from itertools import islice, repeat
from typing import TYPE_CHECKING, Any, Dict, List, Optional, Tuple

import msgspec

import vllm.envs as envs
from vllm.executor.distributed_gpu_executor import (  # yapf: disable
    DistributedGPUExecutor, DistributedGPUExecutorAsync)
from vllm.executor.msgspec_utils import encode_hook
from vllm.executor.ray_utils import RayWorkerWrapper, ray
from vllm.logger import init_logger
from vllm.model_executor.layers.sampler import SamplerOutput
from vllm.sequence import ExecuteModelRequest
from vllm.utils import (_run_task_with_lock, get_distributed_init_method,
                        get_ip, get_open_port, get_vllm_instance_id,
                        make_async)

if ray is not None:
    from ray.util.scheduling_strategies import PlacementGroupSchedulingStrategy

if TYPE_CHECKING:
    from ray.util.placement_group import PlacementGroup

logger = init_logger(__name__)


class RayGPUExecutor(DistributedGPUExecutor):

    uses_ray: bool = True

    def _init_executor(self) -> None:
        self.forward_dag: Optional["ray.dag.CompiledDAG"] = None
        # If the env var is set, it uses the Ray's compiled DAG API
        # which optimizes the control plane overhead.
        # Run vLLM with VLLM_USE_RAY_COMPILED_DAG=1 to enable it.
        # Currently, this requires USE_RAY_SPMD_WORKER=True.
        self.use_ray_compiled_dag = envs.VLLM_USE_RAY_COMPILED_DAG
        # If the env var is set, then we do not distinguish between the
        # "driver worker" vs other workers. Also, the rank 0 worker will
        # be executed in a remote Ray worker. Currently this requires
        # USE_RAY_COMPILED_DAG=True.
        self.use_ray_spmd_worker = envs.VLLM_USE_RAY_SPMD_WORKER
        if self.use_ray_compiled_dag:
            assert self.use_ray_spmd_worker, (
                "VLLM_USE_RAY_COMPILED_DAG=1 requires "
                "VLLM_USE_RAY_SPMD_WORKER=1")
        if self.use_ray_spmd_worker:
            # TODO: Support SPMD worker for non-DAG Ray executor.
            assert self.use_ray_compiled_dag, (
                "VLLM_USE_RAY_SPMD_WORKER=1 requires "
                "VLLM_USE_RAY_COMPILED_DAG=1")

        assert self.uses_ray
        placement_group = self.parallel_config.placement_group

        # Disable Ray usage stats collection.
        ray_usage = os.environ.get("RAY_USAGE_STATS_ENABLED", "0")
        if ray_usage != "1":
            os.environ["RAY_USAGE_STATS_ENABLED"] = "0"

        # Create the parallel GPU workers.
        self._init_workers_ray(placement_group)

        self.input_encoder = msgspec.msgpack.Encoder(enc_hook=encode_hook)
        self.output_decoder = msgspec.msgpack.Decoder(
            Optional[List[SamplerOutput]])

    def shutdown(self) -> None:
        if hasattr(self, "forward_dag") and self.forward_dag is not None:
            self.forward_dag.teardown()
            import ray
            for worker in self.workers:
                ray.kill(worker)
            self.forward_dag = None

    def _configure_ray_workers_use_nsight(self,
                                          ray_remote_kwargs) -> Dict[str, Any]:
        # If nsight profiling is enabled, we need to set the profiling
        # configuration for the ray workers as runtime env.
        runtime_env = ray_remote_kwargs.setdefault("runtime_env", {})
        runtime_env.update({
            "nsight": {
                "t": "cuda,cudnn,cublas",
                "o": "'worker_process_%p'",
                "cuda-graph-trace": "node",
            }
        })

        return ray_remote_kwargs

    def _get_worker_wrapper_args(self) -> Dict[str, Any]:
        (worker_module_name, worker_class_name,
         worker_class_fn) = self._get_worker_module_and_class()

        return dict(
            worker_module_name=worker_module_name,
            worker_class_name=worker_class_name,
            worker_class_fn=worker_class_fn,
            trust_remote_code=self.model_config.trust_remote_code,
        )

    # child class could overwrite this to return actual env vars.
    def _get_env_vars_to_be_updated(self):
        return self._env_vars_for_all_workers

    def _init_workers_ray(self, placement_group: "PlacementGroup",
                          **ray_remote_kwargs):
        if (self.parallel_config.tensor_parallel_size == 1
                and self.parallel_config.pipeline_parallel_size == 1):
            # For single GPU case, we use a ray worker with constrained memory.
            num_gpus = self.cache_config.gpu_memory_utilization
        else:
            # Otherwise, the ray workers are allocated with a full GPU.
            num_gpus = 1

        # The driver dummy worker does not actually use any resources.
        # It holds the resource for the driver worker.
        self.driver_dummy_worker: Optional[RayWorkerWrapper] = None
        # The remaining workers are the actual ray actors.
        self.workers: List[RayWorkerWrapper] = []

        # Used in ray compiled DAG: indexed first by PP rank,
        # and then TP rank. In other words, the inner list is
        # the TP group of workers for a PP rank.
        self.pp_tp_workers: List[List[RayWorkerWrapper]] = []

        if self.parallel_config.ray_workers_use_nsight:
            ray_remote_kwargs = self._configure_ray_workers_use_nsight(
                ray_remote_kwargs)

        logger.info("use_ray_spmd_worker: %s", self.use_ray_spmd_worker)

        # Create the workers.
        driver_ip = get_ip()
        worker_wrapper_kwargs = self._get_worker_wrapper_args()
        for bundle_id, bundle in enumerate(placement_group.bundle_specs):
            if not bundle.get("GPU", 0):
                continue
            scheduling_strategy = PlacementGroupSchedulingStrategy(
                placement_group=placement_group,
                placement_group_capture_child_tasks=True,
                placement_group_bundle_index=bundle_id,
            )

            worker = ray.remote(
                num_cpus=0,
                num_gpus=num_gpus,
                scheduling_strategy=scheduling_strategy,
                **ray_remote_kwargs,
            )(RayWorkerWrapper).remote(**worker_wrapper_kwargs)

            if self.use_ray_spmd_worker:
                self.workers.append(worker)
            else:
                worker_ip = ray.get(worker.get_node_ip.remote())
                if worker_ip == driver_ip and self.driver_dummy_worker is None:
                    # If the worker is on the same node as the driver, we use it
                    # as the resource holder for the driver process.
                    self.driver_dummy_worker = worker
                    self.driver_worker = RayWorkerWrapper(
                        **worker_wrapper_kwargs)
                else:
                    # Else, added to the list of workers.
                    self.workers.append(worker)

        logger.debug("workers: %s", self.workers)
        logger.debug("driver_dummy_worker: %s", self.driver_dummy_worker)
        if not self.use_ray_spmd_worker and self.driver_dummy_worker is None:
            raise ValueError(
                "Ray does not allocate any GPUs on the driver node. Consider "
                "adjusting the Ray placement group or running the driver on a "
                "GPU node.")

        worker_ips = [
            ray.get(worker.get_node_ip.remote())  # type: ignore[attr-defined]
            for worker in self.workers
        ]
        ip_counts: Dict[str, int] = {}
        for ip in worker_ips:
            ip_counts[ip] = ip_counts.get(ip, 0) + 1

        def sort_by_driver_then_worker_ip(worker):
            """
            Sort the workers based on 3 properties:
            1. If the worker is on the same node as the driver (vllm engine),
                it should be placed first.
            2. Then, if the worker is on a node with fewer workers, it should
                be placed first.
            3. Finally, if the work is on a node with smaller IP address, it
                should be placed first.
            """
            ip = ray.get(worker.get_node_ip.remote())
            return (ip != driver_ip, ip_counts[ip], ip)

        # After sorting, the workers on the same node will be
        # close to each other, and the workers on the driver
        # node will be placed first.
        self.workers = sorted(self.workers, key=sort_by_driver_then_worker_ip)

        # Get the set of GPU IDs used on each node.
        worker_node_and_gpu_ids = self._run_workers("get_node_and_gpu_ids",
                                                    use_dummy_driver=True)

        node_workers = defaultdict(list)  # node id -> list of worker ranks
        node_gpus = defaultdict(list)  # node id -> list of gpu ids

        for i, (node_id, gpu_ids) in enumerate(worker_node_and_gpu_ids):
            node_workers[node_id].append(i)
            # `gpu_ids` can be a list of strings or integers.
            # convert them to integers for consistency.
            # NOTE: gpu_ids can be larger than 9 (e.g. 16 GPUs),
            # string sorting is not sufficient.
            # see https://github.com/vllm-project/vllm/issues/5590
            gpu_ids = [int(x) for x in gpu_ids]
            node_gpus[node_id].extend(gpu_ids)
        for node_id, gpu_ids in node_gpus.items():
            node_gpus[node_id] = sorted(gpu_ids)

        all_ips = set(worker_ips + [driver_ip])
        n_ips = len(all_ips)
        n_nodes = len(node_workers)

        if n_nodes != n_ips:
            raise RuntimeError(
                f"Every node should have a unique IP address. Got {n_nodes}"
                f" nodes with node ids {list(node_workers.keys())} and "
                f"{n_ips} unique IP addresses {all_ips}. Please check your"
                " network configuration. If you set `VLLM_HOST_IP` or "
                "`HOST_IP` environment variable, make sure it is unique for"
                " each node.")

        VLLM_INSTANCE_ID = get_vllm_instance_id()

        # Set environment variables for the driver and workers.
        all_args_to_update_environment_variables = [({
            "CUDA_VISIBLE_DEVICES":
            ",".join(map(str, node_gpus[node_id])),
            "VLLM_INSTANCE_ID":
            VLLM_INSTANCE_ID,
            "VLLM_TRACE_FUNCTION":
            str(envs.VLLM_TRACE_FUNCTION),
        }, ) for (node_id, _) in worker_node_and_gpu_ids]

        self._env_vars_for_all_workers = (
            all_args_to_update_environment_variables)

        self._run_workers("update_environment_variables",
                          all_args=self._get_env_vars_to_be_updated())

        if len(node_gpus) == 1:
            # in single node case, we don't need to get the IP address.
            # the loopback address is sufficient
            # NOTE: a node may have several IP addresses, one for each
            # network interface. `get_ip()` might return any of them,
            # while they might not work for communication inside the node
            # if the network setup is complicated. Using the loopback address
            # solves this issue, as it always works for communication inside
            # the node.
            driver_ip = "127.0.0.1"
        distributed_init_method = get_distributed_init_method(
            driver_ip, get_open_port())

        # Initialize the actual workers inside worker wrapper.
        init_worker_all_kwargs = [
            self._get_worker_kwargs(
                local_rank=node_workers[node_id].index(rank),
                rank=rank,
                distributed_init_method=distributed_init_method,
            ) for rank, (node_id, _) in enumerate(worker_node_and_gpu_ids)
        ]
        self._run_workers("init_worker", all_kwargs=init_worker_all_kwargs)

        self._run_workers("init_device")
        self._run_workers("load_model",
                          max_concurrent_workers=self.parallel_config.
                          max_parallel_loading_workers)

        if self.use_ray_spmd_worker:
            for pp_rank in range(self.parallel_config.pipeline_parallel_size):
                self.pp_tp_workers.append([])
                for tp_rank in range(
                        self.parallel_config.tensor_parallel_size):
                    # PP=2, TP=4
                    # pp_tp_workers = [[0, 1, 2, 3], [4, 5, 6, 7]]
                    rank = (pp_rank * self.parallel_config.tensor_parallel_size
                            ) + tp_rank
                    assert len(self.pp_tp_workers[pp_rank]) == tp_rank
                    assert pp_rank < len(self.pp_tp_workers)
                    self.pp_tp_workers[pp_rank].append(self.workers[rank])

        # This is the list of workers that are rank 0 of each TP group EXCEPT
        # global rank 0. These are the workers that will broadcast to the
        # rest of the workers.
        self.tp_driver_workers: List[RayWorkerWrapper] = []
        # This is the list of workers that are not drivers and not the first
        # worker in a TP group. These are the workers that will be
        # broadcasted to.
        self.non_driver_workers: List[RayWorkerWrapper] = []

        # Enforce rank order for correct rank to return final output.
        for index, worker in enumerate(self.workers):
            # The driver worker is rank 0 and not in self.workers.
            rank = index + 1
            if rank % self.parallel_config.tensor_parallel_size == 0:
                self.tp_driver_workers.append(worker)
            else:
                self.non_driver_workers.append(worker)

    def _driver_execute_model(
        self, execute_model_req: Optional[ExecuteModelRequest]
    ) -> Optional[List[SamplerOutput]]:
        """Run execute_model in the driver worker.

        Passing None will cause the driver to stop the model execution
        loop running in each of the remote workers.
        """
        assert not self.use_ray_spmd_worker, (
            "driver_worker does not exist for VLLM_USE_RAY_SPMD_WORKER=1")
        return self.driver_worker.execute_method("execute_model",
                                                 execute_model_req)

    def execute_model(
            self,
            execute_model_req: ExecuteModelRequest) -> List[SamplerOutput]:
        if not self.use_ray_spmd_worker:
            return super().execute_model(execute_model_req)

        if self.forward_dag is None:
            self.forward_dag = self._compiled_ray_dag(enable_asyncio=False)

        serialized_data = self.input_encoder.encode(execute_model_req)
        outputs = ray.get(self.forward_dag.execute(serialized_data))
        output = self.output_decoder.decode(outputs[0])
        return output

    def _run_workers(
        self,
        method: str,
        *args,
        async_run_tensor_parallel_workers_only: bool = False,
        all_args: Optional[List[Tuple[Any, ...]]] = None,
        all_kwargs: Optional[List[Dict[str, Any]]] = None,
        use_dummy_driver: bool = False,
        max_concurrent_workers: Optional[int] = None,
        **kwargs,
    ) -> Any:
        """Runs the given method on all workers. Can be used in the following
        ways:

        Args:
        - async_run_tensor_parallel_workers_only: If True the method will be
          run only in the remote TP workers, not the driver worker.
          It will also be run asynchronously and return a list of futures
          rather than blocking on the results.
        - args/kwargs: All workers share the same args/kwargs
        - all_args/all_kwargs: args/kwargs for each worker are specified
          individually
        """
        if self.use_ray_spmd_worker:
            assert not async_run_tensor_parallel_workers_only, (
                "async_run_tensor_parallel_workers_only is not supported for "
                "spmd mode.")

        if max_concurrent_workers:
            raise NotImplementedError(
                "max_concurrent_workers is not supported yet.")

        count = len(self.workers) if not \
            async_run_tensor_parallel_workers_only \
            else len(self.non_driver_workers)
        # If using SPMD worker, all workers are the same, so we should execute
        # the args on all workers. Otherwise, we skip the first worker's args
        # because those args will go to the driver worker.
        first_worker_args_index: int = 0 if self.use_ray_spmd_worker else 1
        all_worker_args = repeat(args, count) if all_args is None \
            else islice(all_args, first_worker_args_index, None)
        all_worker_kwargs = repeat(kwargs, count) if all_kwargs is None \
            else islice(all_kwargs, first_worker_args_index, None)

        # Start the ray workers first.
        ray_workers = self.workers
        if async_run_tensor_parallel_workers_only:
            ray_workers = self.non_driver_workers
        ray_worker_outputs = [
            worker.execute_method.remote(method, *worker_args, **worker_kwargs)
            for (worker, worker_args, worker_kwargs
                 ) in zip(ray_workers, all_worker_args, all_worker_kwargs)
        ]

        if async_run_tensor_parallel_workers_only:
            # Just return futures
            return ray_worker_outputs

        driver_worker_output = []
        # In SPMD mode, the driver worker is the same as any other worker,
        # so we only explicitly execute on the driver worker if using a
        # non-SPMD worker class.
        if not self.use_ray_spmd_worker:
            driver_args = args if all_args is None else all_args[0]
            driver_kwargs = kwargs if all_kwargs is None else all_kwargs[0]

            # Start the driver worker after all the ray workers.
            if not use_dummy_driver:
                driver_worker_output = [
                    self.driver_worker.execute_method(method, *driver_args,
                                                      **driver_kwargs)
                ]
            else:
                assert self.driver_dummy_worker is not None
                driver_worker_output = [
                    ray.get(
                        self.driver_dummy_worker.execute_method.remote(
                            method, *driver_args, **driver_kwargs))
                ]

        # Get the results of the ray workers.
        if self.workers:
            ray_worker_outputs = ray.get(ray_worker_outputs)

        return driver_worker_output + ray_worker_outputs

    def _wait_for_tasks_completion(self, parallel_worker_tasks: Any) -> None:
        """Wait for futures returned from _run_workers() with
        async_run_remote_workers_only to complete."""
        ray.get(parallel_worker_tasks)

    def _compiled_ray_dag(self, enable_asyncio: bool):
        import pkg_resources
        from packaging import version

        required_version = version.parse("2.32")
        current_version = version.parse(
            pkg_resources.get_distribution("ray").version)
        if current_version < required_version:
            raise ValueError(f"Ray version {required_version} or greater is "
                             f"required, but found {current_version}")

        assert self.parallel_config.use_ray
        from ray.dag import InputNode, MultiOutputNode
        from ray.experimental.channel.torch_tensor_type import TorchTensorType

        logger.info("VLLM_USE_RAY_COMPILED_DAG_NCCL_CHANNEL = %s",
                    envs.VLLM_USE_RAY_COMPILED_DAG_NCCL_CHANNEL)
        with InputNode() as input_data:
            # Example DAG: PP=2, TP=4
            # (ExecuteModelReq, None) -> 0 -> (ExecuteModelReq, IntermediateOutput) -> 4 -> SamplerOutput   # noqa: E501
            #                         -> 1 -> (ExecuteModelReq, IntermediateOutput) -> 5 -> SamplerOutput   # noqa: E501
            #                         -> 2 -> (ExecuteModelReq, IntermediateOutput) -> 6 -> SamplerOutput   # noqa: E501
            #                         -> 3 -> (ExecuteModelReq, IntermediateOutput) -> 7 -> SamplerOutput   # noqa: E501

            # All workers in the first TP group will take in the
            # ExecuteModelRequest as input.
            outputs = [input_data for _ in self.pp_tp_workers[0]]
            for pp_rank, tp_group in enumerate(self.pp_tp_workers):
                # Each PP worker takes in the output of the previous PP worker,
                # and the TP group executes in SPMD fashion.
                outputs = [
                    worker.execute_model_spmd.
                    bind(  # type: ignore[attr-defined]
                        outputs[i]) for i, worker in enumerate(tp_group)
                ]

                last_pp_rank = len(self.pp_tp_workers) - 1
                if pp_rank < last_pp_rank:
                    # Specify how intermediate tensors should be passed
                    # between pp stages, no need to specify for the last
                    # pp stage.
                    transport = "nccl" \
                        if envs.VLLM_USE_RAY_COMPILED_DAG_NCCL_CHANNEL \
                        else "auto"
                    outputs = [
                        output.with_type_hint(
                            TorchTensorType(transport=transport))
                        for output in outputs
                    ]

            forward_dag = MultiOutputNode(outputs)

        return forward_dag.experimental_compile(enable_asyncio=enable_asyncio)

    def __del__(self):
        self.shutdown()


class RayGPUExecutorAsync(RayGPUExecutor, DistributedGPUExecutorAsync):

    def __init__(self, *args, **kwargs):
        super().__init__(*args, **kwargs)
        self.pp_locks: Optional[List[asyncio.Lock]] = None
        self.use_ray_spmd_worker = envs.VLLM_USE_RAY_SPMD_WORKER
        if not self.use_ray_compiled_dag:
            self.driver_exec_method = make_async(
                self.driver_worker.execute_method)

    async def execute_model_async(
            self,
            execute_model_req: ExecuteModelRequest) -> List[SamplerOutput]:
        if not self.use_ray_spmd_worker:
            return await super().execute_model_async(execute_model_req)

        if self.forward_dag is None:
            self.forward_dag = self._compiled_ray_dag(enable_asyncio=True)

        serialized_data = self.input_encoder.encode(execute_model_req)
        dag_future = await self.forward_dag.execute_async(serialized_data)
        outputs = await dag_future
        return self.output_decoder.decode(outputs[0])

    async def _driver_execute_model_async(
        self,
        execute_model_req: Optional[ExecuteModelRequest] = None
    ) -> List[SamplerOutput]:
        assert not self.use_ray_spmd_worker, (
            "driver_worker does not exist for VLLM_USE_RAY_SPMD_WORKER=1")
        if not self.tp_driver_workers:
            return await self.driver_exec_method("execute_model",
                                                 execute_model_req)
        if self.pp_locks is None:
            # This locks each pipeline parallel stage so multiple virtual
            # engines can't execute on the same stage at the same time
            # We create the locks here to avoid creating them in the constructor
            # which uses a different asyncio loop.
            self.pp_locks = [
                asyncio.Lock()
                for _ in range(self.parallel_config.pipeline_parallel_size)
            ]

        tasks = [
            asyncio.create_task(
                _run_task_with_lock(self.driver_exec_method, self.pp_locks[0],
                                    "execute_model", execute_model_req))
        ]
        for pp_rank, driver_worker in enumerate(self.tp_driver_workers,
                                                start=1):
            tasks.append(
                asyncio.create_task(
                    _run_task_with_lock(driver_worker.execute_method.remote,
                                        self.pp_locks[pp_rank],
                                        "execute_model", execute_model_req)))

        results = await asyncio.gather(*tasks)

        # Only the last PP stage has the final results.
        return results[-1]

    async def _start_worker_execution_loop(self):
        assert not self.use_ray_spmd_worker, (
            "worker loop is disabled for VLLM_USE_RAY_SPMD_WORKER=1")
        coros = [
            worker.execute_method.remote("start_worker_execution_loop")
            for worker in self.non_driver_workers
        ]
        return await asyncio.gather(*coros)

    def __del__(self):
        self.shutdown()