- **Add SPDX license headers to python source files** - **Check for SPDX headers using pre-commit** commit 9d7ef44c3cfb72ca4c32e1c677d99259d10d4745 Author: Russell Bryant <rbryant@redhat.com> Date: Fri Jan 31 14:18:24 2025 -0500 Add SPDX license headers to python source files This commit adds SPDX license headers to python source files as recommended to the project by the Linux Foundation. These headers provide a concise way that is both human and machine readable for communicating license information for each source file. It helps avoid any ambiguity about the license of the code and can also be easily used by tools to help manage license compliance. The Linux Foundation runs license scans against the codebase to help ensure we are in compliance with the licenses of the code we use, including dependencies. Having these headers in place helps that tool do its job. More information can be found on the SPDX site: - https://spdx.dev/learn/handling-license-info/ Signed-off-by: Russell Bryant <rbryant@redhat.com> commit 5a1cf1cb3b80759131c73f6a9dddebccac039dea Author: Russell Bryant <rbryant@redhat.com> Date: Fri Jan 31 14:36:32 2025 -0500 Check for SPDX headers using pre-commit Signed-off-by: Russell Bryant <rbryant@redhat.com> --------- Signed-off-by: Russell Bryant <rbryant@redhat.com>
529 lines
22 KiB
Python
529 lines
22 KiB
Python
# SPDX-License-Identifier: Apache-2.0
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import dataclasses
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import itertools
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from typing import Any, Dict, List, Optional, Tuple, Type, cast
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import torch
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import torch.distributed
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from vllm.attention.backends.abstract import (AttentionBackend,
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AttentionMetadata)
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from vllm.attention.backends.utils import PAD_SLOT_ID
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from vllm.attention.selector import (get_env_variable_attn_backend,
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get_global_forced_attn_backend)
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from vllm.config import VllmConfig
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from vllm.forward_context import set_forward_context
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from vllm.inputs import INPUT_REGISTRY, InputRegistry
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from vllm.logger import init_logger
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from vllm.model_executor import SamplingMetadata
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from vllm.model_executor.layers.sampler import SamplerOutput
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from vllm.multimodal import (MULTIMODAL_REGISTRY, MultiModalKwargs,
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MultiModalRegistry)
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from vllm.platforms import _Backend
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from vllm.sampling_params import SamplingParams
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from vllm.sequence import (IntermediateTensors, PoolerOutput,
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SequenceGroupMetadata)
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from vllm.utils import STR_NOT_IMPL_ENC_DEC_BACKEND, make_tensor_with_pad
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from vllm.worker.model_runner import (GPUModelRunnerBase,
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ModelInputForGPUBuilder,
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ModelInputForGPUWithSamplingMetadata)
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from vllm.worker.model_runner_base import (
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_add_attn_metadata_broadcastable_dict,
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_add_sampling_metadata_broadcastable_dict)
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from vllm.worker.utils import assert_enc_dec_mr_supported_scenario
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logger = init_logger(__name__)
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@dataclasses.dataclass(frozen=True)
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class EncoderDecoderModelInput(ModelInputForGPUWithSamplingMetadata):
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"""
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Used by the EncoderDecoderModelRunner.
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"""
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encoder_input_tokens: Optional[torch.Tensor] = None
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encoder_input_positions: Optional[torch.Tensor] = None
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def as_broadcastable_tensor_dict(self) -> Dict[str, Any]:
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tensor_dict = {
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"input_tokens": self.input_tokens,
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"input_positions": self.input_positions,
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"encoder_input_tokens": self.encoder_input_tokens,
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"encoder_input_positions": self.encoder_input_positions,
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"virtual_engine": self.virtual_engine,
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"request_ids_to_seq_ids": self.request_ids_to_seq_ids,
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"finished_requests_ids": self.finished_requests_ids,
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"multi_modal_kwargs": self.multi_modal_kwargs,
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}
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_add_attn_metadata_broadcastable_dict(tensor_dict, self.attn_metadata)
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_add_sampling_metadata_broadcastable_dict(tensor_dict,
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self.sampling_metadata)
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return tensor_dict
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@classmethod
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def from_broadcasted_tensor_dict(
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cls,
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tensor_dict: Dict[str, Any],
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attn_backend: Optional["AttentionBackend"] = None,
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) -> "EncoderDecoderModelInput":
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return cast(
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EncoderDecoderModelInput,
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super().from_broadcasted_tensor_dict(tensor_dict, attn_backend))
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class EncoderDecoderModelRunner(GPUModelRunnerBase[EncoderDecoderModelInput]):
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_model_input_cls: Type[EncoderDecoderModelInput] = (
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EncoderDecoderModelInput)
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_builder_cls: Type[ModelInputForGPUBuilder] = (ModelInputForGPUBuilder)
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def __init__(
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self,
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vllm_config: VllmConfig,
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kv_cache_dtype: Optional[str] = "auto",
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is_driver_worker: bool = False,
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input_registry: InputRegistry = INPUT_REGISTRY,
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mm_registry: MultiModalRegistry = MULTIMODAL_REGISTRY,
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):
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'''
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EncoderDecoderModelRunner constructor.
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`lora_config` and `prompt_adapter_config` are
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unused (since these features are not yet supported for encoder/decoder
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models) but these arguments are present here for compatibility with
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the base-class constructor.
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'''
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self._maybe_force_supported_attention_backend()
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super().__init__(
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vllm_config=vllm_config,
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kv_cache_dtype=kv_cache_dtype,
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is_driver_worker=is_driver_worker,
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)
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# Crash for unsupported encoder/scenarios
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assert_enc_dec_mr_supported_scenario(self)
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def _maybe_force_supported_attention_backend(self):
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'''
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Force vLLM to use the XFormers attention backend,
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which is currently the only supported option.
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'''
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def raise_backend_err():
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# The user has specified an attention backend override
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# which is invalid for encoder/decoder models
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raise NotImplementedError(STR_NOT_IMPL_ENC_DEC_BACKEND)
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maybe_env_var_forced_backend = get_env_variable_attn_backend()
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maybe_global_forced_backend = get_global_forced_attn_backend()
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is_forced_by_global = maybe_global_forced_backend is not None
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is_forced_by_env_var = maybe_env_var_forced_backend is not None
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if is_forced_by_global: # noqa: SIM102
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# Backend override enforced by global variable takes
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# precedence over vLLM backend environment variable.
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if maybe_global_forced_backend not in\
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[_Backend.XFORMERS, _Backend.FLASH_ATTN]:
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raise_backend_err()
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elif is_forced_by_env_var: # noqa: SIM102
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# Backend override enforced by vLLM backend
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# environment variable
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if maybe_env_var_forced_backend not in\
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[_Backend.XFORMERS, _Backend.FLASH_ATTN]:
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raise_backend_err()
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def _list_to_int32_tensor(
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self,
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_list: List[int],
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) -> torch.Tensor:
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return torch.tensor(_list, dtype=torch.int32, device=self.device)
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def _list_to_long_tensor(
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self,
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_list: List[int],
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) -> torch.Tensor:
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return torch.tensor(_list, dtype=torch.long, device=self.device)
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def _empty_int32_tensor(self) -> torch.Tensor:
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return self._list_to_int32_tensor([])
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def _empty_long_tensor(self) -> torch.Tensor:
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return self._list_to_long_tensor([])
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@torch.inference_mode()
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def execute_model(
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self,
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model_input: EncoderDecoderModelInput,
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kv_caches: List[torch.Tensor],
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intermediate_tensors: Optional[IntermediateTensors] = None,
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num_steps: int = 1,
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) -> Optional[List[PoolerOutput]]:
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if num_steps > 1:
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raise ValueError("num_steps > 1 is not supported in "
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"EncoderDecoderModelRunner")
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if (model_input.attn_metadata is not None
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and model_input.attn_metadata.prefill_metadata is None
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and model_input.attn_metadata.decode_metadata.use_cuda_graph):
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assert model_input.input_tokens is not None
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graph_batch_size = model_input.input_tokens.shape[0]
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model_executable = self.graph_runners[
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model_input.virtual_engine][graph_batch_size]
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else:
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model_executable = self.model
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seqlen_agnostic_kwargs = {
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"finished_requests_ids": model_input.finished_requests_ids,
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"request_ids_to_seq_ids": model_input.request_ids_to_seq_ids,
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} if self.has_inner_state else {}
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multi_modal_kwargs = model_input.multi_modal_kwargs or {}
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with set_forward_context(model_input.attn_metadata, self.vllm_config,
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model_input.virtual_engine):
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hidden_or_intermediate_states = model_executable(
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input_ids=model_input.input_tokens,
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positions=model_input.input_positions,
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encoder_input_ids=model_input.encoder_input_tokens,
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encoder_positions=model_input.encoder_input_positions,
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kv_caches=kv_caches,
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attn_metadata=model_input.attn_metadata,
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intermediate_tensors=intermediate_tensors,
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**MultiModalKwargs.as_kwargs(multi_modal_kwargs,
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device=self.device),
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**seqlen_agnostic_kwargs)
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logits = self.model.compute_logits(hidden_or_intermediate_states,
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model_input.sampling_metadata)
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if not self.is_driver_worker:
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return []
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if model_input.async_callback is not None:
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model_input.async_callback()
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# Sample the next token.
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output: SamplerOutput = self.model.sample(
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logits=logits,
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sampling_metadata=model_input.sampling_metadata,
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)
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return [output]
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def make_model_input_from_broadcasted_tensor_dict(
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self, tensor_dict: Dict[str, Any]) -> EncoderDecoderModelInput:
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return EncoderDecoderModelInput.from_broadcasted_tensor_dict(
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tensor_dict,
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attn_backend=self.attn_backend,
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)
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def prepare_model_input(
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self,
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seq_group_metadata_list: List[SequenceGroupMetadata],
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virtual_engine: int = 0,
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finished_requests_ids: Optional[List[str]] = None
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) -> EncoderDecoderModelInput:
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"""Prepare the model input based on a given sequence group, including
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metadata for the sampling step.
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Since chunked prefill is not supported for encoder/decoder models,
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`input_tokens` is assumed to be either entirely prefill tokens or
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entirely decode tokens.
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"""
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model_input = self._prepare_model_input_tensors(
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seq_group_metadata_list, finished_requests_ids)
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(
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attn_metadata,
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encoder_input_tokens_tensor,
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encoder_input_positions_tensor,
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) = (self._prepare_encoder_model_input_tensors(seq_group_metadata_list,
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model_input))
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# Inject attn_metadata encoder/cross-attention fields &
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# encoder input tokens/positions into model_input.
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# Frozen dataclass fields cannot be modified, so use
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# dataclasses.replace to construct a new model input
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# instance.
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model_input = dataclasses.replace(
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model_input,
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attn_metadata=attn_metadata,
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encoder_input_tokens=encoder_input_tokens_tensor,
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encoder_input_positions=encoder_input_positions_tensor,
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)
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generators = self.get_generators(finished_requests_ids)
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sampling_metadata = SamplingMetadata.prepare(seq_group_metadata_list,
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model_input.seq_lens,
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model_input.query_lens,
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self.device,
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self.pin_memory,
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generators=generators)
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is_prompt = (seq_group_metadata_list[0].is_prompt
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if seq_group_metadata_list else None)
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return dataclasses.replace(model_input,
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sampling_metadata=sampling_metadata,
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is_prompt=is_prompt,
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virtual_engine=virtual_engine)
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@torch.inference_mode()
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def profile_run(self) -> None:
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# Enable top-k sampling to reflect the accurate memory usage.
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sampling_params = SamplingParams(top_p=0.99, top_k=self.vocab_size - 1)
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max_num_batched_tokens = self.scheduler_config.max_num_batched_tokens
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max_num_seqs = self.scheduler_config.max_num_seqs
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# Profile memory usage with max_num_sequences sequences and the total
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# number of tokens equal to max_num_batched_tokens.
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seqs: List[SequenceGroupMetadata] = []
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max_mm_tokens = self.mm_registry.get_max_multimodal_tokens(
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self.model_config)
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if max_mm_tokens > 0:
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logger.info("Starting profile run for multi-modal models.")
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batch_size = 0
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for group_id in range(max_num_seqs):
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seq_len = (max_num_batched_tokens // max_num_seqs +
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(group_id < max_num_batched_tokens % max_num_seqs))
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batch_size += seq_len
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decoder_dummy_data = self.input_registry \
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.dummy_data_for_profiling(self.model_config,
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seq_len,
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self.mm_registry,
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is_encoder_data=False)
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encoder_dummy_data = self.input_registry \
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.dummy_data_for_profiling(self.model_config,
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seq_len,
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self.mm_registry,
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is_encoder_data=True)
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# Having more tokens is over-conservative but otherwise fine
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assert len(
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decoder_dummy_data.seq_data.prompt_token_ids
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) >= seq_len, (
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f"Expected at least {seq_len} dummy tokens for profiling, "
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f"but got: {len(decoder_dummy_data.seq_data.prompt_token_ids)}"
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)
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assert decoder_dummy_data.multi_modal_data is None or \
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encoder_dummy_data.multi_modal_data is None, (
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"Multi-modal data can't be provided in both encoder and decoder"
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)
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seq = SequenceGroupMetadata(
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request_id=str(group_id),
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is_prompt=True,
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seq_data={group_id: decoder_dummy_data.seq_data},
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sampling_params=sampling_params,
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block_tables=None,
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encoder_seq_data=encoder_dummy_data.seq_data,
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cross_block_table=None,
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multi_modal_data=decoder_dummy_data.multi_modal_data
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or encoder_dummy_data.multi_modal_data,
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multi_modal_placeholders=decoder_dummy_data.
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multi_modal_placeholders
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or encoder_dummy_data.multi_modal_placeholders)
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seqs.append(seq)
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# Run the model with the dummy inputs.
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num_layers = self.model_config.get_num_layers(self.parallel_config)
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# use an empty tensor instead of `None`` to force Dynamo to pass
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# it by reference, rather by specializing on the value ``None``.
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# the `dtype` argument does not matter, and we use `float32` as
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# a placeholder (it has wide hardware support).
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kv_caches = [
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torch.tensor([], dtype=torch.float32, device=self.device)
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for _ in range(num_layers)
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]
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finished_requests_ids = [seq.request_id for seq in seqs]
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model_input = self.prepare_model_input(
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seqs, finished_requests_ids=finished_requests_ids)
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intermediate_tensors = None
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self.execute_model(model_input, kv_caches, intermediate_tensors)
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torch.cuda.synchronize()
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return
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def _prepare_encoder_model_input_tensors(
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self,
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seq_group_metadata_list: List[SequenceGroupMetadata],
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model_input: EncoderDecoderModelInput,
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) -> Tuple[AttentionMetadata, Optional[torch.Tensor],
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Optional[torch.Tensor]]:
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"""Helper method to prepare the encoder- and cross-attn-related
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model inputs based on a given sequence group. These additional inputs
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are used to augment an already-computed `EncoderDecoderModelInput`
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data structure which already has decoder-related model inputs
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populated.
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Sets the following attn_metadata fields:
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* `num_encoder_tokens`
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* `encoder_seq_lens`
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* `encoder_seq_lens_tensor`
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* `max_encoder_seq_len`
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* `cross_slot_mapping`
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* `cross_block_tables`
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Constructs a new model inputs data structure, based on
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(1) the existing fields in the `model_inputs` argument,
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and (2) the following additional fields which are
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computed (or in the case of `attn_metadata`, updated)
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by this function:
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* attn_metadata
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* encoder_input_tokens
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* encoder_input_positions
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Arguments:
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* seq_group_metadata_list: list of sequence groups for which to
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compute inputs
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* model_inputs: model inputs data structure with decoder-oriented
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fields already computed.
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Return:
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* Updated model inputs data structure
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"""
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if len(seq_group_metadata_list) == 0:
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return (model_input.attn_metadata, None, None)
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# Since we are not supporting chunked prefill either the entire
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# batch is prefill or it is decode
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is_prompt = seq_group_metadata_list[0].is_prompt
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# Build encoder inputs
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encoder_seq_lens: List[int] = []
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if is_prompt:
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# Prefill phase.
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cross_block_tables = self._empty_int32_tensor().view(
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len(seq_group_metadata_list), -1)
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# Extract input tokens/positions, cross-attention slot-mapping,
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# & seq len from each sequence group metadata
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(
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encoder_input_tokens,
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encoder_input_positions,
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cross_slot_mapping,
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) = (
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[],
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[],
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[],
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)
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for seq_group_metadata in seq_group_metadata_list:
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# Build seq lens
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seq_len = seq_group_metadata.encoder_seq_data.get_len()
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token_ids = seq_group_metadata.encoder_seq_data.get_token_ids()
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encoder_seq_lens.append(seq_len)
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# Build slot mapping
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is_profile_run = (seq_group_metadata.block_tables is None)
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if is_profile_run:
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# During memory profiling, the block tables are not
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# initialized yet. In this case, we just use a dummy
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# slot mapping.
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# In embeddings, the block tables are {seq_id: None}.
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cross_slot_mapping.extend([PAD_SLOT_ID] * seq_len)
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else:
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for i in range(0, seq_len):
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block_number = seq_group_metadata.cross_block_table[
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i // self.block_size]
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block_offset = i % self.block_size
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slot = block_number * self.block_size + block_offset
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cross_slot_mapping.append(slot)
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# Build encoder input tokens
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encoder_input_tokens.extend(token_ids)
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encoder_input_positions.extend(list(range(0, seq_len)))
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# Convert tokens/positions & cross-attention
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# slot-mapping to encoder input tensors
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encoder_input_tokens_tensor = self._list_to_long_tensor(
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encoder_input_tokens)
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encoder_input_positions_tensor = self._list_to_long_tensor(
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encoder_input_positions)
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cross_slot_mapping_tensor = self._list_to_long_tensor(
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cross_slot_mapping)
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else:
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# Decode phase.
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encoder_input_tokens_tensor = self._empty_long_tensor()
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encoder_input_positions_tensor = self._empty_long_tensor()
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cross_slot_mapping_tensor = self._empty_long_tensor()
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# Extract cross-attention block tables &
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# seq len from each sequence group metadata.
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# Cross-attention block tables are empty
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# during vLLM memory profiling.
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cross_block_tables = []
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for seq_group_metadata in seq_group_metadata_list:
|
|
for _ in range(len(seq_group_metadata.seq_data)):
|
|
encoder_seq_lens.append(
|
|
seq_group_metadata.encoder_seq_data.get_len())
|
|
cross_block_table = seq_group_metadata.cross_block_table
|
|
cross_block_tables.append([] if (
|
|
cross_block_table is None) else cross_block_table)
|
|
|
|
if (model_input.attn_metadata is not None
|
|
and model_input.attn_metadata.use_cuda_graph):
|
|
# We will be using CUDA graph replay for this decode.
|
|
max_len_of_block_table = self.get_max_block_per_batch()
|
|
batch_size = len(encoder_seq_lens)
|
|
graph_batch_size = self.vllm_config.pad_for_cudagraph(
|
|
batch_size)
|
|
assert graph_batch_size >= batch_size
|
|
cuda_graph_pad_size = graph_batch_size - batch_size
|
|
# extend the cross_block_tables and encoder_seq_lens to match
|
|
# the graph_batch_size.
|
|
cross_block_tables.extend([[]
|
|
for _ in range(cuda_graph_pad_size)
|
|
])
|
|
encoder_seq_lens.extend(
|
|
itertools.repeat(1, cuda_graph_pad_size))
|
|
|
|
else:
|
|
max_len_of_block_table = max(
|
|
len(block_table) for block_table in cross_block_tables)
|
|
|
|
cross_block_tables = make_tensor_with_pad(
|
|
cross_block_tables,
|
|
max_len=max_len_of_block_table,
|
|
pad=0,
|
|
dtype=torch.int32,
|
|
device=self.device,
|
|
)
|
|
|
|
# Compute encoder sequence lengths & encoder
|
|
# sequence starting offset tensors
|
|
max_encoder_seq_len = max(encoder_seq_lens, default=0)
|
|
encoder_seq_lens_tensor = self._list_to_int32_tensor(encoder_seq_lens)
|
|
encoder_seq_start_loc = torch.zeros(encoder_seq_lens_tensor.shape[0] +
|
|
1,
|
|
dtype=torch.int32,
|
|
device=self.device)
|
|
torch.cumsum(encoder_seq_lens_tensor,
|
|
dim=0,
|
|
dtype=encoder_seq_start_loc.dtype,
|
|
out=encoder_seq_start_loc[1:])
|
|
|
|
# Update attention metadata with encoder-oriented attributes
|
|
attn_metadata = model_input.attn_metadata
|
|
assert attn_metadata is not None
|
|
(
|
|
attn_metadata.num_encoder_tokens,
|
|
attn_metadata.encoder_seq_lens,
|
|
attn_metadata.encoder_seq_lens_tensor,
|
|
attn_metadata.max_encoder_seq_len,
|
|
attn_metadata.encoder_seq_start_loc,
|
|
attn_metadata.cross_slot_mapping,
|
|
attn_metadata.cross_block_tables,
|
|
) = (
|
|
sum(encoder_seq_lens),
|
|
encoder_seq_lens,
|
|
encoder_seq_lens_tensor,
|
|
max_encoder_seq_len,
|
|
encoder_seq_start_loc,
|
|
cross_slot_mapping_tensor,
|
|
cross_block_tables,
|
|
)
|
|
|
|
return (attn_metadata, encoder_input_tokens_tensor,
|
|
encoder_input_positions_tensor)
|