[Hardware][Intel-Gaudi] Multi-step scheduling implementation for HPU (#12779)

Signed-off-by: Tomasz Zielinski <tomasz.zielinski@intel.com>
This commit is contained in:
Tomasz Zielinski 2025-04-11 16:38:36 +02:00 committed by GitHub
parent 9e90c9f73f
commit 34b2cf3b33
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3 changed files with 437 additions and 114 deletions

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@ -46,15 +46,15 @@ class HpuPlatform(Platform):
def check_and_update_config(cls, vllm_config: VllmConfig) -> None: def check_and_update_config(cls, vllm_config: VllmConfig) -> None:
scheduler_config = vllm_config.scheduler_config scheduler_config = vllm_config.scheduler_config
parallel_config = vllm_config.parallel_config
if scheduler_config.is_multi_step: if scheduler_config.is_multi_step:
raise NotImplementedError( parallel_config.worker_cls = \
"Multi-step execution is not implemented for HPU") "vllm.worker.multi_step_hpu_worker.MultiStepHPUWorker"
if vllm_config.speculative_config is not None: if vllm_config.speculative_config is not None:
raise NotImplementedError( raise NotImplementedError(
"Speculative decoding is not implemented for HPU") "Speculative decoding is not implemented for HPU")
parallel_config = vllm_config.parallel_config
if parallel_config.worker_cls == "auto": if parallel_config.worker_cls == "auto":
parallel_config.worker_cls = "vllm.worker.hpu_worker.HPUWorker" parallel_config.worker_cls = "vllm.worker.hpu_worker.HPUWorker"

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@ -32,6 +32,7 @@ from vllm_hpu_extension.profiler import (HabanaHighLevelProfiler,
import vllm.envs as envs import vllm.envs as envs
from vllm.attention import AttentionMetadata, get_attn_backend from vllm.attention import AttentionMetadata, get_attn_backend
from vllm.config import DeviceConfig, VllmConfig from vllm.config import DeviceConfig, VllmConfig
from vllm.distributed import broadcast_tensor_dict
from vllm.distributed.parallel_state import get_world_group from vllm.distributed.parallel_state import get_world_group
from vllm.forward_context import set_forward_context from vllm.forward_context import set_forward_context
from vllm.logger import init_logger from vllm.logger import init_logger
@ -44,11 +45,13 @@ from vllm.model_executor.layers.sampler import SamplerOutput
from vllm.model_executor.layers.vocab_parallel_embedding import ( from vllm.model_executor.layers.vocab_parallel_embedding import (
VocabParallelEmbedding) VocabParallelEmbedding)
from vllm.model_executor.model_loader import get_model from vllm.model_executor.model_loader import get_model
from vllm.model_executor.sampling_metadata import SequenceGroupToSample
from vllm.multimodal import (MULTIMODAL_REGISTRY, BatchedTensorInputs, from vllm.multimodal import (MULTIMODAL_REGISTRY, BatchedTensorInputs,
MultiModalKwargs) MultiModalKwargs)
from vllm.sampling_params import SamplingParams from vllm.sampling_params import SamplingParams
from vllm.sequence import (IntermediateTensors, SequenceData, from vllm.sequence import (CompletionSequenceGroupOutput, IntermediateTensors,
SequenceGroupMetadata) Logprob, SequenceData, SequenceGroupMetadata,
SequenceOutput)
from vllm.utils import (bind_kv_cache, is_pin_memory_available, from vllm.utils import (bind_kv_cache, is_pin_memory_available,
make_tensor_with_pad) make_tensor_with_pad)
from vllm.worker.model_runner_base import ( from vllm.worker.model_runner_base import (
@ -100,7 +103,10 @@ def subtuple(obj: object,
if to_override is None: if to_override is None:
to_override = {} to_override = {}
fields = set(to_copy) | set(to_override.keys()) fields = set(to_copy) | set(to_override.keys())
values = {f: to_override.get(f, getattr(obj, f)) for f in fields} if type(obj) is dict:
values = {key: obj[key] for key in fields if key in obj}
else:
values = {f: to_override.get(f, getattr(obj, f)) for f in fields}
if typename not in _TYPE_CACHE: if typename not in _TYPE_CACHE:
_TYPE_CACHE[typename] = collections.namedtuple(typename, _TYPE_CACHE[typename] = collections.namedtuple(typename,
' '.join(fields)) ' '.join(fields))
@ -533,6 +539,8 @@ class ModelInputForHPU(ModelRunnerInputBase):
virtual_engine: int = 0 virtual_engine: int = 0
lora_ids: Optional[List[int]] = None lora_ids: Optional[List[int]] = None
async_callback: Optional[Callable] = None async_callback: Optional[Callable] = None
is_first_multi_step: bool = True
is_last_step: bool = True
def as_broadcastable_tensor_dict(self) -> Dict[str, Any]: def as_broadcastable_tensor_dict(self) -> Dict[str, Any]:
tensor_dict = { tensor_dict = {
@ -545,6 +553,8 @@ class ModelInputForHPU(ModelRunnerInputBase):
"batch_size_padded": self.batch_size_padded, "batch_size_padded": self.batch_size_padded,
"virtual_engine": self.virtual_engine, "virtual_engine": self.virtual_engine,
"lora_ids": self.lora_ids, "lora_ids": self.lora_ids,
"is_first_multi_step": self.is_first_multi_step,
"is_last_step": self.is_last_step,
} }
_add_attn_metadata_broadcastable_dict(tensor_dict, self.attn_metadata) _add_attn_metadata_broadcastable_dict(tensor_dict, self.attn_metadata)
return tensor_dict return tensor_dict
@ -656,6 +666,9 @@ class HPUModelRunnerBase(ModelRunnerBase[TModelInputForHPU]):
self._set_gc_threshold() self._set_gc_threshold()
self.use_contiguous_pa = envs.VLLM_USE_HPU_CONTIGUOUS_CACHE_FETCH self.use_contiguous_pa = envs.VLLM_USE_HPU_CONTIGUOUS_CACHE_FETCH
# For multi-step scheduling
self.cached_step_outputs: List[torch.Tensor] = []
def _set_gc_threshold(self) -> None: def _set_gc_threshold(self) -> None:
# Read https://docs.python.org/3/library/gc.html#gc.set_threshold # Read https://docs.python.org/3/library/gc.html#gc.set_threshold
# for comprehensive description of gc generations. # for comprehensive description of gc generations.
@ -1005,6 +1018,7 @@ class HPUModelRunnerBase(ModelRunnerBase[TModelInputForHPU]):
def _prepare_decode( def _prepare_decode(
self, self,
seq_group_metadata_list: List[SequenceGroupMetadata], seq_group_metadata_list: List[SequenceGroupMetadata],
output=None,
) -> PrepareDecodeMetadata: ) -> PrepareDecodeMetadata:
input_tokens: List[List[int]] = [] input_tokens: List[List[int]] = []
input_positions: List[List[int]] = [] input_positions: List[List[int]] = []
@ -1035,8 +1049,9 @@ class HPUModelRunnerBase(ModelRunnerBase[TModelInputForHPU]):
for seq_id in seq_ids: for seq_id in seq_ids:
seq_data = seq_group_metadata.seq_data[seq_id] seq_data = seq_group_metadata.seq_data[seq_id]
generation_token = seq_data.get_last_token_id() if output is None:
input_tokens.append([generation_token]) generation_token = seq_data.get_last_token_id()
input_tokens.append([generation_token])
seq_len = seq_data.get_len() seq_len = seq_data.get_len()
position = seq_len - 1 position = seq_len - 1
@ -1047,6 +1062,9 @@ class HPUModelRunnerBase(ModelRunnerBase[TModelInputForHPU]):
seq_lens.append(seq_len) seq_lens.append(seq_len)
block_table = seq_group_metadata.block_tables[seq_id] block_table = seq_group_metadata.block_tables[seq_id]
num_fully_occupied_blocks = position // self.block_size
block_table = block_table[:num_fully_occupied_blocks + 1]
if len(block_table) == 0: if len(block_table) == 0:
block_number = _PAD_BLOCK_ID block_number = _PAD_BLOCK_ID
else: else:
@ -1066,9 +1084,14 @@ class HPUModelRunnerBase(ModelRunnerBase[TModelInputForHPU]):
block_table = block_table[-sliding_window_blocks:] block_table = block_table[-sliding_window_blocks:]
block_tables.append(block_table) block_tables.append(block_table)
input_tokens = torch.tensor(input_tokens, if output is None:
dtype=torch.long, input_tokens = torch.tensor(input_tokens,
device=self.device) dtype=torch.long,
device=self.device)
else:
real_batch_size = len(seq_group_metadata_list)
input_tokens = output[:real_batch_size]
input_positions = torch.tensor(input_positions, input_positions = torch.tensor(input_positions,
dtype=torch.long, dtype=torch.long,
device=self.device) device=self.device)
@ -1462,7 +1485,27 @@ class HPUModelRunnerBase(ModelRunnerBase[TModelInputForHPU]):
profiler.start() profiler.start()
for _ in range(times): for _ in range(times):
inputs = self.prepare_model_input(seqs) inputs = self.prepare_model_input(seqs)
self.execute_model(inputs, None, warmup_mode=True) is_single_step = \
self.vllm_config.scheduler_config.num_scheduler_steps == 1
if is_prompt or is_single_step:
self.execute_model(inputs, None, warmup_mode=True)
else: # decode with multi-step
inputs = dataclasses.replace(inputs,
is_first_multi_step=True,
is_last_step=False)
self.execute_model(inputs,
None,
warmup_mode=True,
num_steps=2,
seqs=seqs)
inputs = dataclasses.replace(inputs,
is_first_multi_step=False,
is_last_step=True)
self.execute_model(inputs,
None,
warmup_mode=True,
num_steps=2,
seqs=seqs)
torch.hpu.synchronize() torch.hpu.synchronize()
if profiler: if profiler:
profiler.step() profiler.step()
@ -1985,115 +2028,273 @@ class HPUModelRunner(HPUModelRunnerBase[ModelInputForHPUWithSamplingMetadata]):
intermediate_tensors: Optional[IntermediateTensors] = None, intermediate_tensors: Optional[IntermediateTensors] = None,
num_steps: int = 1, num_steps: int = 1,
warmup_mode=False, warmup_mode=False,
seqs=None,
) -> Optional[Union[List[SamplerOutput], IntermediateTensors]]: ) -> Optional[Union[List[SamplerOutput], IntermediateTensors]]:
if num_steps > 1: if not model_input.is_first_multi_step:
raise ValueError( if not model_input.is_last_step:
"num_steps > 1 is not supported in HPUModelRunner") # not first or last multi-step
return []
# last multi-step
output = self._decode_sampler_outputs(
model_input) if self.is_driver_worker else []
torch.hpu.synchronize()
if model_input.is_first_multi_step:
# first multi-step
if self.lora_config:
assert model_input.lora_requests is not None
assert model_input.lora_mapping is not None
self.set_active_loras(model_input.lora_requests,
model_input.lora_mapping)
input_tokens = model_input.input_tokens
input_positions = model_input.input_positions
attn_metadata = model_input.attn_metadata
sampling_metadata = model_input.sampling_metadata
real_batch_size = model_input.real_batch_size
batch_size_padded = model_input.batch_size_padded
assert input_tokens is not None
assert input_positions is not None
assert sampling_metadata is not None
assert attn_metadata is not None
is_prompt = attn_metadata.is_prompt
assert is_prompt is not None
batch_size = input_tokens.size(0)
seq_len = self._seq_len(attn_metadata)
use_graphs = self._use_graphs(batch_size, seq_len, is_prompt)
self._check_config(batch_size, seq_len, is_prompt, warmup_mode)
if self.lora_config: lora_mask: torch.Tensor = None
assert model_input.lora_requests is not None lora_logits_mask: torch.Tensor = None
assert model_input.lora_mapping is not None if self.lora_config:
self.set_active_loras(model_input.lora_requests, assert model_input.lora_ids is not None
model_input.lora_mapping) lora_mask, lora_logits_mask = self.create_lora_mask(
input_tokens = model_input.input_tokens input_tokens, model_input.lora_ids,
input_positions = model_input.input_positions attn_metadata.is_prompt)
attn_metadata = model_input.attn_metadata
sampling_metadata = model_input.sampling_metadata
real_batch_size = model_input.real_batch_size
batch_size_padded = model_input.batch_size_padded
assert input_tokens is not None
assert input_positions is not None
assert sampling_metadata is not None
assert attn_metadata is not None
is_prompt = attn_metadata.is_prompt
assert is_prompt is not None
batch_size = input_tokens.size(0)
seq_len = self._seq_len(attn_metadata)
use_graphs = self._use_graphs(batch_size, seq_len, is_prompt)
self._check_config(batch_size, seq_len, is_prompt, warmup_mode)
lora_mask: torch.Tensor = None execute_model_kwargs = {
lora_logits_mask: torch.Tensor = None "input_ids": input_tokens,
if self.lora_config: "positions": input_positions,
assert model_input.lora_ids is not None "attn_metadata": self.trim_attn_metadata(attn_metadata),
lora_mask, lora_logits_mask = self.create_lora_mask( "intermediate_tensors": intermediate_tensors,
input_tokens, model_input.lora_ids, attn_metadata.is_prompt) "lora_mask": lora_mask,
"virtual_engine": model_input.virtual_engine,
**(model_input.multi_modal_kwargs or {}),
}
if htorch.utils.internal.is_lazy():
execute_model_kwargs.update(
{"bypass_hpu_graphs": not use_graphs})
execute_model_kwargs = { htorch.core.mark_step()
"input_ids": input_tokens, if self.is_driver_worker:
"positions": input_positions, model_event_name = ("model_"
"attn_metadata": self.trim_attn_metadata(attn_metadata), f"{'prompt' if is_prompt else 'decode'}_"
"intermediate_tensors": intermediate_tensors, f"bs{batch_size}_"
"lora_mask": lora_mask, f"seq{seq_len}_"
"virtual_engine": model_input.virtual_engine, f"graphs{'T' if use_graphs else 'F'}")
**(model_input.multi_modal_kwargs or {}), else:
} model_event_name = 'model_executable'
if htorch.utils.internal.is_lazy(): if num_steps > 1:
execute_model_kwargs.update({"bypass_hpu_graphs": not use_graphs}) # in case of multi-step scheduling
# we only want to pythonize in the last step
sampling_metadata.skip_sampler_cpu_output = True
self.model.model.sampler.include_gpu_probs_tensor = True
cache_orig_output_tokens_len: List[Dict] = []
htorch.core.mark_step() def try_revert_dummy_output_tokens():
if self.is_driver_worker: if len(cache_orig_output_tokens_len) > 0:
model_event_name = ("model_" # Reuse the original output token ids length
f"{'prompt' if is_prompt else 'decode'}_" for i, seq_group_metadata in enumerate(
f"bs{batch_size}_" seq_group_metadata_list):
f"seq{seq_len}_" for j, data in seq_group_metadata.seq_data.items():
f"graphs{'T' if use_graphs else 'F'}") orig_output_tokens_len = \
cache_orig_output_tokens_len[i][j]
data.output_token_ids = \
data.output_token_ids[:orig_output_tokens_len]
for i in range(num_steps):
if i != 0 and not self.is_driver_worker:
broadcast_data = broadcast_tensor_dict(src=0)
if 'early_exit' in broadcast_data and broadcast_data[
'early_exit']:
return [output] if num_steps == 1 else []
execute_model_kwargs.update({
"input_ids":
broadcast_data["input_ids"],
"positions":
broadcast_data["positions"],
"attn_metadata":
self.trim_attn_metadata(
broadcast_data["attn_metadata"])
})
with self.profiler.record_event('internal', model_event_name):
hidden_states = self.model.forward(
**execute_model_kwargs,
selected_token_indices=sampling_metadata.
selected_token_indices)
if self.lora_config:
LoraMask.setLoraMask(
lora_logits_mask.index_select(
0, sampling_metadata.selected_token_indices))
# Compute the logits.
with self.profiler.record_event(
'internal',
('compute_logits_'
f'{"prompt" if is_prompt else "decode"}_bs'
f'{batch_size}_'
f'seq{seq_len}')):
if num_steps == 1:
sampling_metadata.selected_token_indices = None
logits = self.model.compute_logits(hidden_states,
sampling_metadata)
htorch.core.mark_step()
# Only perform sampling in the driver worker.
if not self.is_driver_worker:
continue
if model_input.async_callback is not None:
model_input.async_callback()
# Sample the next token.
with self.profiler.record_event(
'internal', ('sample_'
f'{"prompt" if is_prompt else "decode"}_'
f'bs{batch_size}_'
f'seq{seq_len}')):
output = self.model.sample(
logits=logits,
sampling_metadata=sampling_metadata,
)
if num_steps > 1:
output = output.sampled_token_ids
self.cached_step_outputs.append(
output.detach().clone())
htorch.core.mark_step()
if i < num_steps - 1:
if i == 0:
if model_input.async_callback is not None:
ctx = model_input.async_callback.keywords[ # type: ignore
"ctx"]
seq_group_metadata_list = \
ctx.seq_group_metadata_list
elif seqs is not None:
seq_group_metadata_list = seqs
else:
raise RuntimeError(
"seq_group_metadata_list is uninitialized")
for i, seq_group_metadata in enumerate(
seq_group_metadata_list):
# Skip empty steps
seq_group_metadata.state.current_step += (
num_steps - 2)
# Cache the original output token ids
cache_orig_output_tokens_len.append({})
for j, data in seq_group_metadata.seq_data.items():
cache_orig_output_tokens_len[i][j] = \
len(data.output_token_ids)
for seq_group_metadata in seq_group_metadata_list:
for data in seq_group_metadata.seq_data.values():
max_output_len = sampling_metadata.seq_groups[
0].sampling_params.max_tokens
if len(data.output_token_ids) < max_output_len - 1:
# add a place holder for prepare_decode
# arbitrary value, this could be any token
dummy_token = (540, )
data.output_token_ids += (dummy_token)
else:
broadcast_tensor_dict({'early_exit': True},
src=0)
if num_steps == 1:
return [output]
else:
try_revert_dummy_output_tokens()
return []
result = self._prepare_decode(seq_group_metadata_list,
output=output)
execute_model_kwargs.update({
"input_ids":
result.input_tokens,
"positions":
result.input_positions,
"attn_metadata":
self.trim_attn_metadata(result.attn_metadata)
})
model_kwargs_broadcast_data = {
"input_ids": result.input_tokens,
"positions": result.input_positions,
"attn_metadata": vars(result.attn_metadata)
}
broadcast_tensor_dict(model_kwargs_broadcast_data, src=0)
else:
try_revert_dummy_output_tokens()
if self.is_driver_worker and self.profiler.enabled:
# Stop recording 'execute_model' event
self.profiler.end()
event_end = self.profiler.get_timestamp_us()
counters = self.profiler_counter_helper.get_counter_dict(
cache_config=self.cache_config,
duration=event_end - self.event_start,
seq_len=seq_len,
batch_size_padded=batch_size_padded,
real_batch_size=real_batch_size,
is_prompt=is_prompt)
self.profiler.record_counter(self.event_start, counters)
if num_steps == 1:
return [output] if self.is_driver_worker else []
else:
return []
return output if type(output) is list else [output]
def _decode_sampler_outputs(self, model_input):
use_async_out_proc = model_input.async_callback is not None
sampler_outputs = []
num_outputs = len(self.cached_step_outputs)
for i in range(num_outputs):
next_token_ids = self.cached_step_outputs.pop(0)
next_token_ids = next_token_ids.cpu().tolist()
sampler_output = self._make_decode_output(
next_token_ids, model_input.sampling_metadata.seq_groups)
sampler_outputs.append(sampler_output)
if i < num_outputs - 1 and use_async_out_proc:
assert model_input.async_callback is not None
ctx = model_input.async_callback.keywords[ # type: ignore
"ctx"]
ctx.append_output(
outputs=[sampler_output],
seq_group_metadata_list=ctx.seq_group_metadata_list,
scheduler_outputs=ctx.scheduler_outputs,
is_async=False,
is_last_step=False,
is_first_step_output=False)
model_input.async_callback()
if use_async_out_proc:
return [sampler_outputs[-1]]
else: else:
model_event_name = 'model_executable' return sampler_outputs
with self.profiler.record_event('internal', model_event_name):
hidden_states = self.model.forward(
**execute_model_kwargs,
selected_token_indices=sampling_metadata.selected_token_indices
)
if self.lora_config: def _make_decode_output(
LoraMask.setLoraMask( self,
lora_logits_mask.index_select( next_token_ids: List[List[int]],
0, sampling_metadata.selected_token_indices)) seq_groups: List[SequenceGroupToSample],
) -> SamplerOutput:
# Compute the logits. zero_logprob = Logprob(0.0)
with self.profiler.record_event( sampler_outputs = []
'internal', ('compute_logits_' batch_idx = 0
f'{"prompt" if is_prompt else "decode"}_bs' for seq_group in seq_groups:
f'{batch_size}_' seq_ids = seq_group.seq_ids
f'seq{seq_len}')): seq_outputs = []
sampling_metadata.selected_token_indices = None for seq_id in seq_ids:
logits = self.model.compute_logits(hidden_states, next_token_id = next_token_ids[batch_idx][0]
sampling_metadata) seq_outputs.append(
htorch.core.mark_step() SequenceOutput(seq_id, next_token_id,
# Only perform sampling in the driver worker. {next_token_id: zero_logprob}))
if not self.is_driver_worker: batch_idx += 1
return [] sampler_outputs.append(
CompletionSequenceGroupOutput(seq_outputs, None))
if model_input.async_callback is not None: return SamplerOutput(sampler_outputs)
model_input.async_callback()
# Sample the next token.
with self.profiler.record_event(
'internal', ('sample_'
f'{"prompt" if is_prompt else "decode"}_'
f'bs{batch_size}_'
f'seq{seq_len}')):
output = self.model.sample(
logits=logits,
sampling_metadata=sampling_metadata,
)
output.outputs = output.outputs[:real_batch_size]
htorch.core.mark_step()
if self.is_driver_worker and self.profiler.enabled:
# Stop recording 'execute_model' event
self.profiler.end()
event_end = self.profiler.get_timestamp_us()
counters = self.profiler_counter_helper.get_counter_dict(
cache_config=self.cache_config,
duration=event_end - self.event_start,
seq_len=seq_len,
batch_size_padded=batch_size_padded,
real_batch_size=real_batch_size,
is_prompt=is_prompt)
self.profiler.record_counter(self.event_start, counters)
return [output]
def shutdown_inc(self): def shutdown_inc(self):
can_finalize_inc = False can_finalize_inc = False

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@ -0,0 +1,122 @@
# SPDX-License-Identifier: Apache-2.0
###############################################################################
# Copyright (C) 2025 Habana Labs, Ltd. an Intel Company
###############################################################################
import dataclasses
from typing import Dict, Optional, Tuple
import torch
from vllm.distributed import broadcast_tensor_dict
from vllm.sequence import ExecuteModelRequest
from vllm.worker.hpu_model_runner import ModelInputForHPU
from vllm.worker.hpu_worker import HPUWorker
from vllm.worker.worker_base import WorkerInput
class MultiStepHPUWorker(HPUWorker):
def __init__(self, *args, **kwargs):
super().__init__(*args, **kwargs)
self.cached_model_input: Optional[ModelInputForHPU] = None
def _get_driver_input_and_broadcast(
self, execute_model_req: ExecuteModelRequest
) -> Tuple[ModelInputForHPU, WorkerInput, Dict[str, torch.Tensor]]:
"""
Get the driver input and broadcast it to other workers.
"""
assert self.is_driver_worker
assert execute_model_req.virtual_engine == 0
is_first_multi_step = execute_model_req.is_first_multi_step
is_last_step = execute_model_req.is_last_step
if is_first_multi_step:
# on first step we prepare the worker input and model input normally
worker_input: WorkerInput = self.prepare_worker_input(
execute_model_req=execute_model_req)
worker_input = dataclasses.replace(
worker_input,
num_steps=execute_model_req.num_lookahead_slots + 1)
model_input: ModelInputForHPU = (
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 execute_model_req.async_callback:
model_input = dataclasses.replace(
model_input,
async_callback=execute_model_req.async_callback)
else:
# on subsequent steps we reuse the worker input and model input
assert self.cached_model_input is not None
model_input = self.cached_model_input
worker_input = WorkerInput()
model_input = dataclasses.replace(
model_input,
is_first_multi_step=is_first_multi_step,
is_last_step=is_last_step)
if self.do_metadata_broadcast:
if is_first_multi_step:
broadcast_data = worker_input.as_broadcastable_tensor_dict()
broadcast_data.update(
model_input.as_broadcastable_tensor_dict())
broadcast_tensor_dict(broadcast_data, src=0)
else:
broadcast_data = {
"is_first_multi_step": is_first_multi_step,
"is_last_step": is_last_step,
}
broadcast_tensor_dict(broadcast_data, src=0)
# Returning empty dict here to keep this compatible with
# `LocalOrDistributedWorkerBase._get_driver_input_and_broadcast`
return model_input, worker_input, {}
def prepare_input(
self,
execute_model_req: Optional[ExecuteModelRequest] = None,
) -> Optional[Tuple[ModelInputForHPU, WorkerInput, Dict[str,
torch.Tensor]]]:
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
model_input, worker_input, _ = self._get_driver_input_and_broadcast(
execute_model_req)
if model_input.is_first_multi_step:
self.cached_model_input = model_input
return model_input, worker_input, {}
else:
broadcast_data = broadcast_tensor_dict(src=0)
if not broadcast_data:
return None
if len(broadcast_data) == 2:
assert self.cached_model_input is not None
self.cached_model_input = dataclasses.replace(
self.cached_model_input,
is_first_multi_step=broadcast_data["is_first_multi_step"],
is_last_step=broadcast_data["is_last_step"])
empty_worker_input = WorkerInput()
return self.cached_model_input, empty_worker_input, {}
worker_input = WorkerInput.from_broadcasted_tensor_dict(
broadcast_data)
model_input = (
self.model_runner.
make_model_input_from_broadcasted_tensor_dict(broadcast_data))
self.cached_model_input = model_input
return model_input, worker_input, {}