462 lines
13 KiB
Python
462 lines
13 KiB
Python
# coding: utf-8
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import io
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import json
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import logging
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import os
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import socket
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import time
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import cupy
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import numpy as np
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import torch
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import ray
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import ray.cloudpickle as pickle
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import ray.cluster_utils
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from ray._private.ray_microbenchmark_helpers import timeit
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from ray.air._internal import torch_utils
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from ray.dag import DAGContext, InputNode
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from ray.util.collective.collective_group import nccl_util
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logger = logging.getLogger(__name__)
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SHAPE = None
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DTYPE = torch.float16
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NUM_ITERS = 10
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@ray.remote
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class TorchIpcWorker:
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def __init__(self):
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self.device = torch_utils.get_devices()[0]
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def send(self, shape, dtype, value: int):
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t = torch.ones(shape, dtype=dtype, device=self.device) * value
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if self.device.type == "cuda":
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# NOTE(swang): This is needed because the IPC can get sent before
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# the value has been written to memory. But somehow the read value
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# is still the wrong one?
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torch.cuda.synchronize()
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h = cupy.cuda.runtime.ipcGetMemHandle(t.data_ptr())
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return h
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def recv(self, device_ptr, num_bytes, shape, dtype):
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h = cupy.cuda.runtime.ipcOpenMemHandle(device_ptr)
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m = cupy.cuda.UnownedMemory(h, num_bytes, None)
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m_ptr = cupy.cuda.MemoryPointer(m, 0)
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tensor = torch.tensor(cupy.ndarray(shape, dtype, m_ptr), device=self.device)
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assert tensor.device == self.device
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return (tensor[0].item(), tensor.shape, tensor.dtype)
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@ray.remote
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class TorchTensorWorker:
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def __init__(self):
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self.device = torch_utils.get_devices()[0]
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def send(self, shape, dtype, _):
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t = torch.ones(shape, dtype=dtype, device=self.device) * 1
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return t
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def recv(self, tensor):
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# This benchmark tests the overhead of sending a tensor between
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# actors. To minimize the overhead of shared memory transfer,
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# we return only a byte string.
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assert tensor.device == self.device
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return b"x"
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@ray.remote(num_gpus=1)
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class NcclWorker:
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def __init__(self, rank):
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self.rank = rank
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def get_node_id(self):
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return ray.get_runtime_context().get_node_id()
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def init(self, world_size):
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from ray.air._internal import torch_utils
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self.device = torch_utils.get_devices()[0]
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self.world_size = world_size
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torch.distributed.init_process_group(
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backend="nccl",
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world_size=world_size,
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rank=self.rank,
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)
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def _send(self, buf, num_el, rank):
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torch.distributed.send(buf, rank)
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def _recv(self, buf, num_el, rank):
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torch.distributed.recv(buf, rank)
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def do_send_recv(self, shape, dtype):
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other_rank = (self.rank + 1) % self.world_size
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def _run():
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if self.rank == 0:
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i = np.random.randint(100)
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input_buffer = torch.ones(shape, dtype=dtype, device=self.device) * i
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self._send(input_buffer, input_buffer.numel(), other_rank)
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else:
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input_buffer = torch.empty(shape, dtype=dtype, device=self.device)
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self._recv(input_buffer, input_buffer.numel(), other_rank)
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torch.cuda.synchronize()
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return timeit("exec_nccl_gpu", _run)
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def exec_ray_dag(
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label,
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sender,
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receiver,
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use_nccl=False,
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use_cgraph=True,
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static_shape=False,
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direct_return=False,
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):
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# Test torch.Tensor sent between actors.
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with InputNode() as inp:
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dag = sender.send.bind(SHAPE, DTYPE, inp)
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if use_cgraph:
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dag = dag.with_tensor_transport(
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transport="nccl" if use_nccl else "auto",
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_static_shape=static_shape,
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_direct_return=direct_return,
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)
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dag = receiver.recv.bind(dag)
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if use_cgraph:
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dag = dag.experimental_compile()
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def _run():
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ref = dag.execute(b"x")
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result = ray.get(ref)
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assert result == b"x"
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else:
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def _run():
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result = ray.get(dag.execute(b"x"))
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assert result == b"x"
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results = timeit(label, _run)
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if use_cgraph:
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dag.teardown()
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# Workaround for Ray bug in reusing GPUs too quickly.
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# See https://github.com/ray-project/ray/issues/44821.
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ray.kill(sender)
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ray.kill(receiver)
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time.sleep(1)
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return results
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def exec_ray_dag_ipc(label, sender, receiver, use_nccl=False):
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# Test torch.Tensor sent between actors.
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with InputNode() as inp:
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dag = sender.send.bind(SHAPE, DTYPE, inp)
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dag = receiver.recv.bind(
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dag,
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# torch.float16 has item size of 2 bytes.
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SHAPE[0] * 2,
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SHAPE,
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nccl_util.TORCH_NUMPY_DTYPE_MAP[DTYPE],
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)
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compiled_dag = dag.experimental_compile(_buffer_size_bytes=int(SHAPE[0] * 3))
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# Flag that each run can set if it sees incorrect results.
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ok = [True]
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def _run():
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i = np.random.randint(100)
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ref = compiled_dag.execute(i)
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result = ray.get(ref)
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if result != (i, SHAPE, DTYPE):
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ok[0] = False
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results = timeit(label, _run)
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if not ok[0]:
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logger.warning("IPC DAG returned incorrect result")
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compiled_dag.teardown()
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return results
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def _exec_torch_cpu_cpu():
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i = np.random.randint(100)
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t = torch.ones(SHAPE, dtype=DTYPE) * i
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t2 = t.to(copy=True)
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assert (t2[0].item(), t2.shape, t2.dtype) == (i, SHAPE, DTYPE)
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def _exec_torch_gpu():
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i = np.random.randint(100)
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device_from = torch.device("cuda:1")
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device_to = torch.device("cuda:0")
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t = torch.ones(SHAPE, dtype=DTYPE, device=device_from) * i
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t2 = t.to(device_to)
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torch.cuda.synchronize(device_to)
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assert (t2[0].item(), t2.shape, t2.dtype) == (i, SHAPE, DTYPE)
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def exec_nccl_gpu(sender_hint, receiver_hint):
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workers = [
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NcclWorker.options(**sender_hint).remote(0),
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NcclWorker.options(**receiver_hint).remote(1),
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]
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# node_id = ray.get(workers[0].get_node_id.remote())
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# head_node = [node for node in ray.nodes() if node["NodeID"] == node_id]
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# assert len(head_node) == 1
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# head_node = head_node[0]
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# rank_0_addr = f"{head_node['NodeManagerAddress']}:8888"
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ray.get([worker.init.remote(2) for worker in workers])
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tasks = [worker.do_send_recv.remote(SHAPE, DTYPE) for worker in workers]
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done_refs, _ = ray.wait(tasks, num_returns=1)
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results = ray.get(done_refs[0])
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# Workaround for Ray bug in reusing GPUs too quickly.
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# See https://github.com/ray-project/ray/issues/44821.
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for worker in workers:
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ray.kill(worker)
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time.sleep(1)
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return results
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def _exec_torch_gpu_cpu_gpu():
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i = np.random.randint(100)
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device_from = torch.device("cuda:0")
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device_to = torch.device("cuda:1")
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t = torch.ones(SHAPE, dtype=DTYPE, device=device_from) * i
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t = t.to("cpu")
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t2 = t.to(device_to)
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torch.cuda.synchronize(device_to)
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assert (t2[0].item(), t2.shape, t2.dtype) == (i, SHAPE, DTYPE)
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def _exec_pickle_cpu():
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i = np.random.randint(100)
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t = torch.ones(SHAPE, dtype=DTYPE) * i
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byte_stream = io.BytesIO()
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pickle.dump(t, byte_stream)
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byte_stream.seek(0)
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pickle.load(byte_stream)
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def _exec_pickle_gpu():
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i = np.random.randint(100)
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t = torch.ones(SHAPE, dtype=DTYPE, device="cuda") * i
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byte_stream = io.BytesIO()
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pickle.dump(t, byte_stream)
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byte_stream.seek(0)
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pickle.load(byte_stream)
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def _exec_ray_put_cpu():
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i = np.random.randint(100)
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t = torch.ones(SHAPE, dtype=DTYPE) * i
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ray.get(ray.put(t))
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def _exec_ray_put_np_zero_copy():
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i = np.random.randint(100)
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t = torch.ones(SHAPE, dtype=DTYPE) * i
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torch.as_tensor(ray.get(ray.put(t.numpy())))
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def _exec_ray_put_gpu():
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i = np.random.randint(100)
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t = torch.ones(SHAPE, dtype=DTYPE, device="cuda") * i
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ray.get(ray.put(t))
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def exec_ray_dag_cpu(sender_hint, receiver_hint):
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sender = TorchTensorWorker.options(**sender_hint).remote()
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receiver = TorchTensorWorker.options(**receiver_hint).remote()
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return exec_ray_dag("exec_ray_dag_cpu", sender, receiver)
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def exec_ray_core_cpu(sender_hint, receiver_hint):
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time.sleep(1)
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sender = TorchTensorWorker.options(**sender_hint).remote()
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receiver = TorchTensorWorker.options(**receiver_hint).remote()
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return exec_ray_dag("exec_ray_core_cpu", sender, receiver, use_cgraph=False)
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def exec_ray_dag_gpu_ipc_gpu():
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time.sleep(1)
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sender = TorchIpcWorker.options(num_gpus=1).remote()
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receiver = TorchIpcWorker.options(num_gpus=1).remote()
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return exec_ray_dag_ipc("exec_ray_dag_gpu_ipc_gpu", sender, receiver)
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def exec_ray_dag_gpu_cpu_gpu(sender_hint, receiver_hint):
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time.sleep(1)
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sender = TorchTensorWorker.options(num_gpus=1, **sender_hint).remote()
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receiver = TorchTensorWorker.options(num_gpus=1, **receiver_hint).remote()
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return exec_ray_dag("exec_ray_dag_gpu_cpu_gpu", sender, receiver)
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def exec_ray_dag_gpu_nccl(
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sender_hint,
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receiver_hint,
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static_shape: bool = False,
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direct_return: bool = False,
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):
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time.sleep(1)
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sender = TorchTensorWorker.options(num_gpus=1, **sender_hint).remote()
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receiver = TorchTensorWorker.options(num_gpus=1, **receiver_hint).remote()
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return exec_ray_dag(
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"exec_ray_dag_gpu_nccl"
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+ ("_static_shape" if static_shape else "")
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+ ("_direct_return" if direct_return else ""),
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sender,
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receiver,
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use_nccl=True,
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static_shape=static_shape,
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direct_return=direct_return,
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)
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def exec_ray_core_gpu(sender_hint, receiver_hint):
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time.sleep(1)
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sender = TorchTensorWorker.options(num_gpus=1, **sender_hint).remote()
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receiver = TorchTensorWorker.options(num_gpus=1, **receiver_hint).remote()
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return exec_ray_dag("exec_ray_core_gpu", sender, receiver, use_cgraph=False)
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def main(distributed):
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results = []
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ray.init(
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runtime_env={
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"env_vars": {
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"CUDA_VISIBLE_DEVICES": "0,1",
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# Needed for torch distributed.
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"MASTER_ADDR": socket.gethostbyname(socket.gethostname()),
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"MASTER_PORT": "8888",
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}
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}
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)
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# NCCL takes a while to warm up on multi node so increase the default
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# timeout.
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ctx = DAGContext.get_current()
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ctx.get_timeout = 120
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sender_hint, receiver_hint = {}, {}
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if distributed:
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local_node_id = ray.get_runtime_context().get_node_id()
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node_ids = [node["NodeID"] for node in ray.nodes()]
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remote_node_ids = [node_id for node_id in node_ids if node_id != local_node_id]
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assert remote_node_ids
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remote_node_id = remote_node_ids[0]
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# Pin sender on local node and receiver on the other node for consistent
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# results.
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sender_hint = {"label_selector": {ray._raylet.RAY_NODE_ID_KEY: local_node_id}}
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receiver_hint = {
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"label_selector": {ray._raylet.RAY_NODE_ID_KEY: remote_node_id}
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}
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if not distributed:
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results += timeit("exec_torch_cpu_cpu", _exec_torch_cpu_cpu)
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results += timeit("exec_torch_gpu", _exec_torch_gpu)
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results += timeit("exec_torch_gpu_cpu_gpu", _exec_torch_gpu_cpu_gpu)
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results += exec_nccl_gpu(sender_hint, receiver_hint)
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if not distributed:
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results += timeit("exec_ray_put_cpu", _exec_ray_put_cpu)
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results += timeit("exec_ray_put_np_zero_copy", _exec_ray_put_np_zero_copy)
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results += timeit("exec_ray_put_gpu", _exec_ray_put_gpu)
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results += exec_ray_core_cpu(sender_hint, receiver_hint)
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results += exec_ray_dag_cpu(sender_hint, receiver_hint)
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results += exec_ray_core_gpu(sender_hint, receiver_hint)
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results += exec_ray_dag_gpu_cpu_gpu(sender_hint, receiver_hint)
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results += exec_ray_dag_gpu_nccl(
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sender_hint, receiver_hint, static_shape=True, direct_return=True
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)
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results += exec_ray_dag_gpu_nccl(
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sender_hint, receiver_hint, static_shape=False, direct_return=True
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)
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results += exec_ray_dag_gpu_nccl(
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sender_hint, receiver_hint, static_shape=True, direct_return=False
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)
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results += exec_ray_dag_gpu_nccl(
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sender_hint, receiver_hint, static_shape=False, direct_return=False
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)
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return results
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def to_dict_key(key: str):
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for r in [" ", ":", "-"]:
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key = key.replace(r, "_")
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for r in ["(", ")"]:
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key = key.replace(r, "")
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return key
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if __name__ == "__main__":
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import argparse
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parser = argparse.ArgumentParser()
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parser.add_argument(
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"--tensor-size-bytes",
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type=int,
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# 100KB
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default=100_000,
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)
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parser.add_argument(
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"--distributed",
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action="store_true",
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help="Whether this is running on more than one node",
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)
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args = parser.parse_args()
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# Divide by 2 because we're using torch.float16.
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SHAPE = (args.tensor_size_bytes // 2,)
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results = main(args.distributed)
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result_dict = {
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f"{to_dict_key(v[0])}": (v[1], v[2]) for v in results if v is not None
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}
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perf_metrics = [
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{
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"perf_metric_name": to_dict_key(v[0]),
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"perf_metric_value": v[1],
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"perf_metric_type": "THROUGHPUT",
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}
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for v in results
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if v is not None
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]
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result_dict["perf_metrics"] = perf_metrics
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test_output_json = os.environ.get(
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"TEST_OUTPUT_JSON", "/tmp/microbenchmark_gpu.json"
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)
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with open(test_output_json, "wt") as f:
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json.dump(result_dict, f)
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