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242 lines
12 KiB
Python
242 lines
12 KiB
Python
# Note: this code is being actively modified by justheuristic. If you want to change anything about it, please warn me.
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import contextlib
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from typing import AsyncIterator, Dict, Sequence
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import torch
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from hivemind import DHT, P2PContext, TensorDescriptor, deserialize_torch_tensor, nested_flatten, serialize_torch_tensor
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from hivemind.moe.server.connection_handler import ConnectionHandler
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from hivemind.proto import runtime_pb2
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from hivemind.utils.asyncio import anext
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from hivemind.utils.streaming import split_for_streaming
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from hivemind.p2p.p2p_daemon import DEFAULT_MAX_MSG_SIZE
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from hivemind.utils import as_aiter
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from src.data_structures import CHAIN_DELIMITER, ModuleUID
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from src.server.backend import MAX_LENGTH, TransformerBackend
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class TransformerConnectionHandler(ConnectionHandler):
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"""Handles three request types: forward, backward and forward-incremental (inference)"""
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module_backends: Dict[ModuleUID, TransformerBackend]
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def __init__(self, dht: DHT, module_backends: Dict[str, TransformerBackend]):
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super().__init__(dht, module_backends)
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for module_backend in self.module_backends.values():
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assert isinstance(module_backend, TransformerBackend)
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async def rpc_inference(
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self, requests: AsyncIterator[runtime_pb2.ExpertRequest], context: P2PContext
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) -> AsyncIterator[runtime_pb2.ExpertRequest]:
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"""Compute a single step of inference using attention cache; update attention cache accordingly."""
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try:
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print("OPENED RPC_INFERENCE")
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request = await anext(requests)
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requested_uids = self._check_header(request)
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requested_backends = tuple(self.module_backends[uid] for uid in requested_uids)
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cache_metadata = torch.tensor([[-1, -1]], dtype=torch.int64) # [cache_handle, prefix_length]
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prefix_length = 0
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async with self._allocate_caches(requested_backends) as cache_handles:
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assert len(cache_handles) == len(requested_backends)
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while request.tensors: # iterate while user is willing to supply tensors
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hidden_states = [deserialize_torch_tensor(tensor) for tensor in request.tensors]
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# run request tensors through all requested modules, update caches
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for backend, cache_handle in zip(requested_backends, cache_handles):
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cache_metadata[0, 0], cache_metadata[0, 1] = cache_handle, prefix_length
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assert (
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len(hidden_states) == 1 and hidden_states[0].ndim == 3
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), f"inputs to {type(backend)} must be a list with a single 3d tensor of hidden states"
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hidden_states = await backend.inference_pool.submit_task(cache_metadata, *hidden_states)
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assert isinstance(hidden_states, (list, tuple))
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assert len(hidden_states) == 1 and hidden_states[0].ndim == 3
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# serialize and send last layer outputs
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yield runtime_pb2.ExpertResponse(
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tensors=[
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serialize_torch_tensor(result, proto.compression, allow_inplace=True)
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for result, proto in zip(
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hidden_states, nested_flatten(requested_backends[-1].outputs_schema)
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)
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]
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)
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# prepare for next step
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prefix_length += hidden_states[0].shape[1]
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request = await (anext(requests))
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finally:
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print("CLOSED RPC_INFERENCE")
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async def rpc_forward(self, request: runtime_pb2.ExpertRequest, context: P2PContext) -> runtime_pb2.ExpertResponse:
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# Parse request and prepare backends
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hidden_states = [deserialize_torch_tensor(tensor) for tensor in request.tensors]
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requested_uids = self._check_header(request)
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requested_backends = tuple(self.module_backends[uid] for uid in requested_uids)
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# Run a chain of requested backends
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for backend in requested_backends:
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assert isinstance(hidden_states, (list, tuple))
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assert (
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len(hidden_states) == 1 and hidden_states[0].ndim == 3
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), f"inputs to {type(backend)} must be a list with a single 3d tensor of hidden states"
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hidden_states = await backend.forward_pool.submit_task(*hidden_states)
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# Serialize the overall output and respond
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assert len(hidden_states) == 1 and hidden_states[0].ndim == 3
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return runtime_pb2.ExpertResponse(tensors=[
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serialize_torch_tensor(result, proto.compression, allow_inplace=True)
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for result, proto in zip(
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hidden_states, nested_flatten(requested_backends[-1].outputs_schema)
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)
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])
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async def rpc_forward_stream(
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self, requests: AsyncIterator[runtime_pb2.ExpertRequest], context: P2PContext
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) -> AsyncIterator[runtime_pb2.ExpertRequest]:
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# Parse requests and prepare backends
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uids_header, hidden_states = await self._gather_inputs(requests, context)
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requested_uids = self._check_header_str(uids_header)
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requested_backends = tuple(self.module_backends[uid] for uid in requested_uids)
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# Run a chain of requested backends
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for backend in requested_backends:
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assert isinstance(hidden_states, (list, tuple))
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assert (
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len(hidden_states) == 1 and hidden_states[0].ndim == 3
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), f"inputs to {type(backend)} must be a list with a single 3d tensor of hidden states"
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hidden_states = await backend.forward_pool.submit_task(*hidden_states)
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# Serialize the overall output
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assert len(hidden_states) == 1 and hidden_states[0].ndim == 3
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serialized_output = [
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serialize_torch_tensor(result, proto.compression, allow_inplace=True)
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for result, proto in zip(
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hidden_states, nested_flatten(requested_backends[-1].outputs_schema)
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)
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]
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# Split the serialized_output for streaming and respond
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output_split = [
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part
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for tensor in serialized_output
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for part in split_for_streaming(tensor, DEFAULT_MAX_MSG_SIZE)
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]
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async for part in as_aiter(*output_split):
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yield runtime_pb2.ExpertResponse(tensors=[part])
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async def rpc_backward(
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self, request: runtime_pb2.ExpertRequest, context: P2PContext
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) -> runtime_pb2.ExpertResponse:
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# Parse requests and prepare backends
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inputs, grads = [deserialize_torch_tensor(tensor) for tensor in request.tensors]
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requested_uids = self._check_header(request)
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requested_backends = tuple(self.module_backends[uid] for uid in requested_uids)
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# Run a forward chain to collect intermediate inputs
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# Note that we do not forward for the last module since we do not need its output
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inter_inputs = [inputs]
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for backend in requested_backends[:-1]:
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assert (inputs.ndim == 3
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), f"inputs to {type(backend)} must be a single 3d tensor of hidden states"
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inputs = await backend.forward_pool.submit_task(inputs)
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assert (isinstance(inputs, (list, tuple)) and len(inputs) == 1)
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inputs = inputs[0]
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inter_inputs.append(inputs)
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# Run a chain of requested backends
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for inp, backend in zip(inter_inputs[::-1], requested_backends[::-1]):
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inputs_and_grads = [inp, grads]
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grads = await backend.backward_pool.submit_task(*inputs_and_grads)
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assert (isinstance(grads, (list, tuple)) and len(grads) == 1)
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grads = grads[0]
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# Serialize the overall grad_input and respond
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return runtime_pb2.ExpertResponse(tensors=[
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serialize_torch_tensor(result, proto.compression, allow_inplace=True)
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for result, proto in zip(
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[grads], nested_flatten(requested_backends[0].grad_inputs_schema)
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)
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])
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async def rpc_backward_stream(
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self, requests: AsyncIterator[runtime_pb2.ExpertRequest], context: P2PContext
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) -> AsyncIterator[runtime_pb2.ExpertResponse]:
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uids_header, inputs_and_grads = await self._gather_inputs(requests, context)
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inputs, grads = inputs_and_grads
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requested_uids = self._check_header_str(uids_header)
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requested_backends = tuple(self.module_backends[uid] for uid in requested_uids)
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# Run a forward chain to collect intermediate inputs
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# Note that we do not forward for the last module since we do not need its outputs
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inter_inputs = [inputs]
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for backend in requested_backends[:-1]:
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assert (inputs.ndim == 3
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), f"inputs to {type(backend)} must be a single 3d tensor of hidden states"
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inputs = await backend.forward_pool.submit_task(inputs)
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assert (isinstance(inputs, (list, tuple)) and len(inputs) == 1)
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inputs = inputs[0]
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inter_inputs.append(inputs)
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# Run a backward chain for requested backends
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for inp, backend in zip(inter_inputs[::-1], requested_backends[::-1]):
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inputs_and_grads = [inp, grads]
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grads = await backend.backward_pool.submit_task(*inputs_and_grads)
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assert (isinstance(grads, (list, tuple)) and len(grads) == 1)
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grads = grads[0]
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# Serialize the overall grad_inputs
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serialized_grad_inputs = [
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serialize_torch_tensor(result, proto.compression, allow_inplace=True)
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for result, proto in zip(
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[grads], nested_flatten(requested_backends[0].grad_inputs_schema)
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)
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]
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# Split the serialized_grad_inputs for streaming and respond
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output_split = [
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part
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for tensor in serialized_grad_inputs
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for part in split_for_streaming(tensor, DEFAULT_MAX_MSG_SIZE)
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]
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async for part in as_aiter(*output_split):
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yield runtime_pb2.ExpertResponse(tensors=[part])
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def _check_header(self, request: runtime_pb2.ExpertRequest) -> Sequence[ModuleUID]:
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"""Check that the first request to rpc_inference is valid"""
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uids = (request.uid or "").split(CHAIN_DELIMITER)
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if not uids:
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raise RuntimeError("User did not provide any uids")
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for uid in uids:
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if uid not in self.module_backends:
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raise RuntimeError(f"Remote peer does not serve {uid}")
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return tuple(uids)
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def _check_header_str(self, header) -> Sequence[ModuleUID]:
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"""Check that the first request to rpc_inference is valid"""
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uids = (header or "").split(CHAIN_DELIMITER)
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if not uids:
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raise RuntimeError("User did not provide any uids")
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for uid in uids:
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if uid not in self.module_backends:
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raise RuntimeError(f"Remote peer does not serve {uid}")
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return tuple(uids)
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@contextlib.asynccontextmanager
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async def _allocate_caches(self, backends: Sequence[TransformerBackend]) -> Sequence[int]:
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"""Allocate memory caches for each transformer block, return cache handles"""
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async with contextlib.AsyncExitStack() as stack:
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handles = []
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for backend in backends:
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num_heads = backend.module.self_attention.num_heads
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head_dim = backend.module.self_attention.head_dim
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cache_descriptor = TensorDescriptor(size=(2, 1, MAX_LENGTH, num_heads, head_dim), dtype=torch.float32)
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# [key_or_value, batch_size, max_length, num_heads, head_dim]
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handles.append(await stack.enter_async_context(backend.memory_cache.allocate_cache(cache_descriptor)))
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yield handles
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